\input texinfo @c -*-texinfo-*-

@c ----------------------------------------------------------------------------
@c This is the Texinfo source file for the GPROFNG manual.
@c
@c Author: Ruud van der Pas
@c ----------------------------------------------------------------------------

@c %**start of header

@setfilename gprofng.info
@settitle GNU gprofng

@c -- Set the indent for the @example command to 1 space, not 5 ---------------
@exampleindent 1

@c %**end of header

@c -- Start a new chapter on a new, odd numbered, page ------------------------
@setchapternewpage odd

@c -- Merge all index entries into the Concepts Index -------------------------
@syncodeindex fn cp
@syncodeindex ky cp
@syncodeindex pg cp
@syncodeindex vr cp

@c -- Macro definitions -------------------------------------------------------
@c
@c Since only letters can be used, we use capitalization to distinguish
@c different words.
@c ----------------------------------------------------------------------------
@macro CollectApp{}
@command{gprofng collect app}
@end macro

@macro DisplayHTML{}
@command{gprofng display html}
@end macro

@macro DisplayText{}
@command{gprofng display text}
@end macro

@macro Driver{}
@command{gprofng}
@end macro

@macro ProductName{}
gprofng
@end macro

@macro ToolName{}
@command{gprofng}
@end macro

@macro IndexSubentry{label, string}
@c -- @cindex \label\ @subentry \string\
@cindex \label\, \string\
@end macro

@c -- Get the version information ---------------------------------------------
@include version.texi

@c -- Entry for the Info dir structure ----------------------------------------
@ifnottex
@dircategory Software development
@direntry
* gprofng: (gprofng).                    The next generation profiling tool for Linux
@end direntry
@end ifnottex

@c -- Copyright stuff ---------------------------------------------------------
@copying
This document is the manual for @ProductName{}, last updated @value{UPDATED}.

Copyright @copyright{} 2022-2023 Free Software Foundation, Inc.

@c -- @quotation
Permission is granted to copy, distribute and/or modify this document
under the terms of the GNU Free Documentation License,
Version 1.3 or any later version published by the Free Software
Foundation; with no Invariant Sections, with no Front-Cover texts,
and with no Back-Cover Texts.  A copy of the license is included in the
section entitled ``GNU Free Documentation License.''

@c -- @end quotation
@end copying

@finalout
@smallbook

@c -- Define the title page ---------------------------------------------------
@titlepage
@title GNU gprofng
@subtitle The next generation profiling tool for Linux
@subtitle version @value{VERSION} (last updated @value{UPDATED})
@author Ruud van der Pas
@page
@vskip 0pt plus 1filll
@insertcopying
@end titlepage

@c -- Generate the Table of Contents ------------------------------------------
@contents

@c -- The Top node ------------------------------------------------------------
@c Should contain a short summary, copying permissions and a master menu.
@c ----------------------------------------------------------------------------
@ifnottex
@node Top
@top  GNU Gprofng

@insertcopying
@end ifnottex

@ifinfo
@c -- The menu entries --------------------------------------------------------

@menu
* Introduction::           About this manual.
* Overview::               A brief overview of @ProductName{}.
* A Mini Tutorial::        A short tutorial covering the key features.
* Terminology::            Various concepts and some terminology explained.
* Other Document Formats:: How to create this document in other formats.
* Index::                  The index.

@detailmenu

--- The Detailed Node Listing ---

Introduction

Overview

* Main Features::                     A high level overview.
* Sampling versus Tracing::           The pros and cons of sampling versus tracing.
* Steps Needed to Create a Profile::  How to create a profile.

A Mini Tutorial

* Getting Started::                 The basics of profiling with @ProductName().
* Support for Multithreading::      Commands specific to multithreaded applications.
* Viewing Multiple Experiments::    Analyze multiple experiments.
* Profile Hardware Event Counters:: How to use hardware event counters.
* Java Profiling::                  How to profile a Java application.

Terminology

* The Program Counter::                    What is a Program Counter?
* Inclusive and Exclusive Metrics::        An explanation of inclusive and exclusive metrics.
* Metric Definitions::                     Definitions associated with metrics.
* The Viewmode::                           Select the way call stacks are presented.
* The Selection List::                     How to define a selection.
* Load Objects and Functions::             The components in an application.
* The Concept of a CPU in @ProductName{}:: The definition of a CPU.
* Hardware Event Counters Explained::      What are event counters?
* apath::                                  Our generic definition of a path.

@c -- Index

@end detailmenu
@end menu
@end ifinfo

@c -- A new node --------------------------------------------------------------
@node    Introduction
@chapter Introduction
@c ----------------------------------------------------------------------------
The @ProductName{} tool is the next generation profiler for Linux. It consists 
of various commands to generate and display profile information.

This manual starts with a tutorial how to create and interpret a profile. This
part is highly practical and has the goal to get users up to speed as quickly
as possible. As soon as possible, we would like to show you how to get your
first profile on your screen.

This is followed by more examples, covering many of the features. At the
end of this tutorial, you should feel confident enough to tackle the more
complex tasks.

In a future update a more formal reference manual will be included as well.
Since even in this tutorial we use certain terminology, we have included a
chapter with descriptions at the end. In case you encounter unfamiliar 
wordings or terminology, please check this chapter.

One word of caution. In several cases we had to somewhat tweak the screen
output in order to make it fit. This is why the output may look somewhat
different when you try things yourself.

For now, we wish you a smooth profiling experience with @ProductName{} and 
good luck tackling performance bottlenecks.

@c -- A new node --------------------------------------------------------------
@c cccccc @node    A Brief Overview of @ProductName{}
@node    Overview
@chapter A Brief Overview of @ProductName{}
@c ----------------------------------------------------------------------------

@menu
* Main Features::                     A high level overview.
* Sampling versus Tracing::           The pros and cons of sampling versus tracing.
* Steps Needed to Create a Profile::  How to create a profile.
@end menu

Before we cover this tool in quite some detail, we start with a brief overview
of what it is, and the main features. Since we know that many of you would 
like to get started rightaway, already in this first chapter we explain the
basics of profiling with @ToolName{}.

@c ----------------------------------------------------------------------------
@c TBD Review this text. Probably be more specific on the gcc releases and
@c processor specifics.
@c ----------------------------------------------------------------------------

@c -- A new node --------------------------------------------------------------
@node    Main Features
@section Main Features
@c ----------------------------------------------------------------------------

@noindent
These are the main features of the @ProductName{} tool:

@itemize @bullet

@item
Profiling is supported for an application written in C, C++, Java, or Scala.

@c TBD Java: up to 1.8 full support, support other than for modules 

@item
Shared libraries are supported. The information is presented at the instruction
level.

@item
The following multithreading programming models are supported: Pthreads,
OpenMP, and Java threads.

@item
This tool works with unmodified production level executables. There is no need to 
recompile the code, but if the @code{-g} option has been used when building
the application, source line level information is available.

@item
The focus is on support for code generated with the @code{gcc} compiler, but 
there is some limited support for the @code{icc} compiler as well. Future
improvements and enhancements will focus on @code{gcc} though.

@item
Processors from Intel, AMD, and Arm are supported, but the level of support
depends on the architectural details. In particular, hardware event counters
may not be supported.

@item 
Several views into the data are supported. For example, a function overview
where the time is spent, but also a source line, disassembly, call tree and 
a caller-callees overview are available.

@item
Through filters, the user can zoom in on an area of interest.

@item
Two or more profiles can be aggregated, or used in a comparison. This comparison 
can be obtained at the function, source line, and disassembly level.

@item
Through a scripting language, and customization of the metrics shown,
the generation and creation of a profile can be fully automated and provide 
tailored output.

@end itemize

@c -- A new node --------------------------------------------------------------
@node    Sampling versus Tracing
@section Sampling versus Tracing
@c ----------------------------------------------------------------------------

A key difference with some other profiling tools is that the main data 
collection command @CollectApp{} mostly uses 
@cindex Program Counter sampling
@cindex PC sampling
Program Counter (PC) sampling
under the hood. 

With @emph{sampling}, the executable is stopped at regular intervals. Each time
it is halted, key information is gathered and stored. This includes the Program
Counter that keeps track of where the execution is. Hence the name.

Together with operational
data, this information is stored in the experiment directory and can be
viewed in the second phase.

For example, the PC information is used to derive where the program was when
it was halted. Since the sampling interval is known, it is relatively easy to 
derive how much time was spent in the various parts of the program.

The opposite technique is generally referred to as @emph{tracing}. With
tracing, the target is instrumented with specific calls that collect the
requested information.

These are some of the pros and cons of PC sampling verus tracing:

@itemize

@item
Since there is no need to recompile, existing executables can be used
and the profile measures the behaviour of exactly the same executable that is
used in production runs.

With sampling, one inherently profiles a different executable because
the calls to the instrumentation library may affect the compiler optimizations 
and run time behaviour. 

@item
With sampling, there are very few restrictions on what can be profiled and even without
access to the source code, a basic profile can be made.

@item
A downside of sampling is that, depending on the sampling frequency, small 
functions may be missed or not captured accurately. Although this is rare, 
this may happen and is the reason why the user has control over the sampling rate.

@item
While tracing produces precise information, sampling is statistical in nature.
As a result, small variations may occur across seemingly identical runs. We
have not observed more than a few percent deviation though. Especially if 
the target job executed for a sufficiently long time.

@item
With sampling, it is not possible to get an accurate count how often
functions are called.

@end itemize

@c -- A new node --------------------------------------------------------------
@node    Steps Needed to Create a Profile
@section Steps Needed to Create a Profile
@c ----------------------------------------------------------------------------

Creating a profile takes two steps. First the profile data needs to be 
generated. This is followed by a viewing step to create a report from the
information that has been gathered.

Every @ProductName{} command starts with @ToolName{}, the name of the driver. This is followed
by a keyword to define the high level functionality. Depending on this
keyword, a third qualifier may be needed to further narrow down the request. 
This combination is then followed by options that are specific to the functionality
desired.

The command to gather, or ``collect'', the performance data is called 
@CollectApp{}. Aside from numerous options, this command takes the name
of the target executable as an input parameter.

Upon completion of the run, the performance data can be
found in the newly created 
@cindex Experiment directory
experiment directory.

Unless explicitly specified otherwise, a default
name for this directory is chosen. The name is @code{test.<n>.er} where
@code{n} is the first integer number not in use yet for such a name.

For example, the first time @CollectApp{} is invoked, an experiment
directory with the name @code{test.1.er} is created.

Upon a subsequent invocation of @CollectApp{} in the same directory,
an experiment directory with the name @code{test.2.er} will be created, 
and so forth.

Note that @CollectApp{} supports an option to explicitly name the experiment directory.
Outside of the restriction that the name of this directory has to end
with @code{.er}, any valid directory name can be used for this.

Now that we have the performance data, the next step is to display it.

@pindex @DisplayText{}
The most commonly used command to view the performance information is 
@DisplayText{}. This is a very extensive and customizable tool that 
produces the information in ASCII format. 

@pindex @DisplayHTML{}
Another option is to use @DisplayHTML{}. This tool generates a directory with 
files in html format. These can be viewed in a browser, allowing for easy 
navigation through the profile data.

@c -- A new node --------------------------------------------------------------
@node    A Mini Tutorial 
@chapter A Mini Tutorial 
@c ----------------------------------------------------------------------------

In this chapter we present and discuss the main functionality of @ToolName{}.
This will be a practical approach, using an example code to generate profile
data and show how to get various performance reports. 

@menu
* Getting Started::                 The basics of profiling with @ProductName().
* Support for Multithreading::      Commands specific to multithreaded applications.
* Viewing Multiple Experiments::    Analyze multiple experiments.
* Profile Hardware Event Counters:: How to use hardware event counters.
* Java Profiling::                  How to profile a Java application.
@end menu

@c -- A new node --------------------------------------------------------------
@node    Getting Started
@section Getting Started
@c ----------------------------------------------------------------------------

The information presented here provides a good and common basis for many 
profiling tasks, but there are more features that you may want to leverage.

These are covered in subsequent sections in this chapter.

@menu
* The Example Program::                        A description of the example program used.
* A First Profile::                            How to get the first profile.
* The Source Code View::                       Display the metrics in the source code.
* The Disassembly View::                       Display the metrics at the instruction level.
* Display and Define the Metrics::             An example how to customize the metrics.
* A First Customization of the Output::        An example how to customize the output.
* Name the Experiment Directory::              Change the name of the experiment directory.
* Control the Number of Lines in the Output::  Change the number of lines in the tables.
* Sorting the Performance Data::               How to set the metric to sort by.
* Scripting::                                  Use a script to execute the commands.
* A More Elaborate Example::                   An example of customization.
* The Call Tree::                              Display the dynamic call tree.
* More Information on the Experiment::         How to get additional statistics.
* Control the Sampling Frequency::             How to control the sampling granularity.
* Information on Load Objects::                How to get more information on load objects.
@end menu

@c -- A new node --------------------------------------------------------------
@node       The Example Program
@subsection The Example Program
@c ----------------------------------------------------------------------------

Throughout this guide we use the same example C code that implements the 
multiplication of a vector of length @math{n} by an @math{m} by @math{n}
matrix. The result is stored in a vector of length @math{m}. 
@cindex Pthreads
@cindex Posix Threads
The algorithm has been parallelized using Posix Threads, or Pthreads for short.

The code was built using the @code{gcc} compiler and the name of the executable 
is
@cindex mxv-pthreads.exe
mxv-pthreads.exe.

The matrix sizes can be set through the @code{-m} and @code{-n} options. The
number of threads is set with the @code{-t} option. To increase the duration
of the run, the multiplication is executed repeatedly. 

This is an example that multiplies a @math{3000} by @math{2000} matrix with
a vector of length @math{2000} using @math{2} threads:

@smallexample
@verbatim
$ ./mxv-pthreads.exe -m 3000 -n 2000 -t 2
mxv: error check passed - rows = 3000 columns = 2000 threads = 2
$
@end verbatim
@end smallexample

The program performs an internal check to verify the results are correct.
The result of this check is printed, followed by the matrix sizes and the 
number of threads used.

@c -- A new node --------------------------------------------------------------
@node       A First Profile
@subsection A First Profile
@c ----------------------------------------------------------------------------

The first step is to collect the performance data. It is important to remember
that much more information is gathered than may be shown by default. Often a
single data collection run is sufficient to get a lot of insight.

The @CollectApp{} command is used for the data collection. Nothing needs to be
changed in the way the application is executed. The only difference is that it
is now run under control of the tool, as shown below:

@cartouche
@smallexample
$ gprofng collect app ./mxv.pthreads.exe -m 3000 -n 2000 -t 1
@end smallexample
@end cartouche

This command produces the following output:

@smallexample
@verbatim
Creating experiment database test.1.er (Process ID: 2416504) ...
mxv: error check passed - rows = 3000 columns = 2000 threads = 1
@end verbatim
@end smallexample

We see the message that a directory with the name @code{test.1.er} 
has been created. 
The application then completes as usual and we have our first experiment 
directory that can be analyzed.

The tool we use for this is called @DisplayText{}. It takes the name of
the experiment directory as an argument.

@cindex Interpreter mode 
If invoked this way, the tool starts in the interactive @emph{interpreter} mode.
While in this environment, commands can be given and the tool responds. This is
illustrated below:

@smallexample
@verbatim
$ gprofng display text test.1.er
Warning: History and command editing is not supported on this system.
(gp-display-text) quit
$
@end verbatim
@end smallexample

@cindex Command line mode 
While useful in certain cases, we prefer to use this tool in command line mode,
by specifying the commands to be issued when invoking the tool. The way to do
this is to prepend the command with a hyphen (@code{-}) if used on the command
line.

For example,
@IndexSubentry{Commands, @code{functions}}
with the @code{functions} command we request a list of the functions that 
have been executed and their respective CPU times:

@cartouche
@smallexample
$ gprofng display text -functions test.1.er
@end smallexample
@end cartouche

@smallexample
@verbatim
$ gprofng display text -functions test.1.er
Functions sorted by metric: Exclusive Total CPU Time

Excl.     Incl.      Name
Total     Total
CPU sec.  CPU sec.
2.272     2.272      <Total>
2.160     2.160      mxv_core
0.047     0.103      init_data
0.030     0.043      erand48_r
0.013     0.013      __drand48_iterate
0.013     0.056      drand48
0.008     0.010      _int_malloc
0.001     0.001      brk
0.001     0.002      sysmalloc
0.        0.001      __default_morecore
0.        0.113      __libc_start_main
0.        0.010      allocate_data
0.        2.160      collector_root
0.        2.160      driver_mxv
0.        0.113      main
0.        0.010      malloc
0.        0.001      sbrk
@end verbatim
@end smallexample

As easy and simple as these steps are, we do have a first profile of our program!
There are three columns. The first two contain the 
@cindex Total CPU time
@emph{Total CPU Time}, 
which 
is the sum of the user and system time. @xref{Inclusive and Exclusive Metrics}
for an explanation of ``exclusive'' and ``inclusive'' times.

The first line echoes the metric that is used to sort the output. By default, this
is the exclusive CPU time, but the sort metric can be changed by the user.

We then see three columns with the exclusive and inclusive CPU times, plus the
name of the function.

@IndexSubentry{Miscellaneous, @code{<Total>}}
The function with the name @code{<Total>} is not a user function, but is introduced
by @ToolName{} and is used to display the accumulated metric values. In this case,
we see that the total CPU time of this job was @code{2.272} seconds.

With @code{2.160} seconds, function @code{mxv_core} is the most time 
consuming function. It is also a leaf function.

The next function in the list is @code{init_data}. Although the CPU time spent in
this part is negligible, this is an interesting entry because the inclusive CPU
time of @code{0.103} seconds is higher than the exclusive CPU time of @code{0.047}
seconds. Clearly it is calling another function,
or even more than one function. 
@xref{The Call Tree} for the details how to get more information on this.

The function @code{collector_root} does not look familiar. It is one of the internal
functions used by @CollectApp{} and can be ignored. While the inclusive time is high,
the exclusive time is zero. This means it doesn't contribute to the performance.

The question is how we know where this function originates from? There is a very useful
command to get more details on a function. @xref{Information on Load Objects}.

@c -- A new node --------------------------------------------------------------
@node       The Source Code View
@subsection The Source Code View
@c ----------------------------------------------------------------------------

In general, you would like to focus the tuning efforts on the most time
consuming part(s) of the program. In this case that is easy, since 2.160
seconds on a total of 2.272 seconds is spent in function @code{mxv_core}. 
That is 95% of the total and it is time to dig deeper and look
@cindex Source level timings
at the time distribution at the source code level.

@IndexSubentry{Commands, @code{source}}
The @code{source} command is used to accomplish this. It takes the name of the
function, not the source filename, as an argument. This is demonstrated
below, where the @DisplayText{} command is used to show the annotated
source listing of function @code{mxv_core}.

Please note that the source code has to be compiled with the @code{-g}
option in order for the source code feature to work. Otherwise the
location can not be determined.

@cartouche
@smallexample
$ gprofng display text -source mxv_core test.1.er
@end smallexample
@end cartouche

The slightly modified output is as follows:

@smallexample
@verbatim
Source file: <apath>/mxv.c
Object file: mxv-pthreads.exe (found as test.1.er/archives/...)
Load Object: mxv-pthreads.exe (found as test.1.er/archives/...)

   Excl.     Incl.
   Total     Total
   CPU sec.  CPU sec.

   <lines deleted>
                               <Function: mxv_core>
   0.        0.             32. void __attribute__ ((noinline)) 
                                mxv_core (
                                uint64_t row_index_start, 
                                uint64_t row_index_end,
                                uint64_t m, uint64_t n, 
                                double **restrict A,
                                double *restrict b, 
                                double *restrict c)
   0.        0.             33. {
   0.        0.             34.    for (uint64_t i=row_index_start; 
                                        i<=row_index_end; i++) {
   0.        0.             35.       double row_sum = 0.0;
## 1.687     1.687          36.       for (int64_t j=0; j<n; j++)
   0.473     0.473          37.          row_sum += A[i][j]*b[j];
   0.        0.             38.       c[i] = row_sum;
                            39.    }
   0.        0.             40. }
@end verbatim
@end smallexample

The first three lines provide information on the location of the source file,
the object file and the load object (@xref{Load Objects and Functions}).

Function @code{mxv_core} is part of a source file that has other functions
as well. These functions will be shown, but without timing information. They
have been removed in the output shown above.

This is followed by the annotated source code listing. The selected metrics 
are shown first, followed by a source line number, and the source code.
@IndexSubentry{Miscellaneous ,@code{##}}
The most time consuming line(s) are marked with the @code{##} symbol. In
this way they are easier to find.

What we see is that all of the time is spent in lines 36-37. 

@IndexSubentry{Commands, @code{lines}}
A related command sometimes comes handy as well. It is called @code{lines}
and displays a list of the source lines and their metrics, ordered according
to the current sort metric (@xref{Sorting the Performance Data}).

Below the command and the output. For lay-out reasons, only the top 10 is 
shown here and the last part of the text on some lines has been replaced
by dots.

@cartouche
@smallexample
$ gprofng display text -lines test.1.er
@end smallexample
@end cartouche

@smallexample
@verbatim
Lines sorted by metric: Exclusive Total CPU Time

Excl.     Incl.  Name
Total     Total
CPU sec.  CPU sec.
2.272     2.272  <Total>
1.687     1.687  mxv_core, line 36 in "mxv.c"
0.473     0.473  mxv_core, line 37 in "mxv.c"
0.032     0.088  init_data, line 72 in "manage_data.c"
0.030     0.043  <Function: erand48_r, instructions without line numbers>
0.013     0.013  <Function: __drand48_iterate, instructions without ...>
0.013     0.056  <Function: drand48, instructions without line numbers>
0.012     0.012  init_data, line 77 in "manage_data.c"
0.008     0.010  <Function: _int_malloc, instructions without ...>
0.003     0.003  init_data, line 71 in "manage_data.c"
@end verbatim
@end smallexample

What this overview immediately highlights is that the next most time consuming
source line takes 0.032 seconds only. With an inclusive time of 0.088 seconds,
it is also clear that this branch of the code does not impact the performance.

@c -- A new node --------------------------------------------------------------
@node       The Disassembly View
@subsection The Disassembly View
@c ----------------------------------------------------------------------------

The source view is very useful to obtain more insight where the time is spent,
but sometimes this is not sufficient. This is when the disassembly view comes
in. It is activated with the 
@IndexSubentry{Commands, @code{disasm}}
@code{disasm} 
command and as with the source view, it displays an annotated listing. In this
@cindex Instruction level timings
case it shows the instructions with the metrics, interleaved with the
source lines. The
instructions have a reference in square brackets (@code{[} and @code{]})
to the source line they correspond to.

@noindent
This is what we get for our example:

@cartouche
@smallexample
$ gprofng display text -disasm mxv_core test.1.er
@end smallexample
@end cartouche

@smallexample
@verbatim
Source file: <apath>/mxv.c
Object file: mxv-pthreads.exe (found as test.1.er/archives/...)
Load Object: mxv-pthreads.exe (found as test.1.er/archives/...)

   Excl.     Incl.
   Total     Total
   CPU sec.  CPU sec.

   <lines deleted>
                        32. void __attribute__ ((noinline)) 
                            mxv_core (
                            uint64_t row_index_start, 
                            uint64_t row_index_end,
                            uint64_t m, uint64_t n, 
                            double **restrict A,
                            double *restrict b, 
                            double *restrict c)
                        33. {
                            <Function: mxv_core>
   0.        0.             [33]   4021ba:  mov    0x8(%rsp),%r10
                        34.    for (uint64_t i=row_index_start;
                                    i<=row_index_end; i++) {
   0.        0.             [34]   4021bf:  cmp    %rsi,%rdi
   0.        0.             [34]   4021c2:  jbe    0x37
   0.        0.             [34]   4021c4:  ret
                        35.        double row_sum = 0.0;
                        36.        for (int64_t j=0; j<n; j++)
                        37.           row_sum += A[i][j]*b[j];
   0.        0.             [37]   4021c5:  mov    (%r8,%rdi,8),%rdx
   0.        0.             [36]   4021c9:  mov    $0x0,%eax
   0.        0.             [35]   4021ce:  pxor   %xmm1,%xmm1
   0.002     0.002          [37]   4021d2:  movsd  (%rdx,%rax,8),%xmm0
   0.096     0.096          [37]   4021d7:  mulsd  (%r9,%rax,8),%xmm0
   0.375     0.375          [37]   4021dd:  addsd  %xmm0,%xmm1
## 1.683     1.683          [36]   4021e1:  add    $0x1,%rax
   0.004     0.004          [36]   4021e5:  cmp    %rax,%rcx
   0.        0.             [36]   4021e8:  jne    0xffffffffffffffea
                        38.        c[i] = row_sum;
   0.        0.             [38]   4021ea:  movsd  %xmm1,(%r10,%rdi,8)
   0.        0.             [34]   4021f0:  add    $0x1,%rdi
   0.        0.             [34]   4021f4:  cmp    %rdi,%rsi
   0.        0.             [34]   4021f7:  jb     0xd
   0.        0.             [35]   4021f9:  pxor   %xmm1,%xmm1
   0.        0.             [36]   4021fd:  test   %rcx,%rcx
   0.        0.             [36]   402200:  jne    0xffffffffffffffc5
   0.        0.             [36]   402202:  jmp    0xffffffffffffffe8
                        39.    }
                        40. }
   0.        0.             [40]   402204:  ret
@end verbatim
@end smallexample

For each instruction, the timing values are given and we can exactly which ones
are the most expensive. As with the source level view, the most expensive 
instructions are market with the @code{##} symbol.

As illustrated below and similar to the @code{lines} command, we can get 
an overview of the instructions executed by using the 
@IndexSubentry{Commands, @code{pcs}}
@code{pcs} 
command. 

@noindent
Below the command and the output, which again has been restricted
to 10 lines:

@cartouche
@smallexample
$ gprofng display text -pcs test.1.er
@end smallexample
@end cartouche

@smallexample
@verbatim
PCs sorted by metric: Exclusive Total CPU Time

Excl.     Incl.      Name
Total     Total
CPU sec.  CPU sec.
2.272     2.272  <Total>
1.683     1.683  mxv_core + 0x00000027, line 36 in "mxv.c"
0.375     0.375  mxv_core + 0x00000023, line 37 in "mxv.c"
0.096     0.096  mxv_core + 0x0000001D, line 37 in "mxv.c"
0.027     0.027  init_data + 0x000000BD, line 72 in "manage_data.c"
0.012     0.012  init_data + 0x00000117, line 77 in "manage_data.c"
0.008     0.008  _int_malloc + 0x00000A45
0.007     0.007  erand48_r + 0x00000062
0.006     0.006  drand48 + 0x00000000
0.005     0.005  __drand48_iterate + 0x00000005
@end verbatim
@end smallexample

@c -- A new node --------------------------------------------------------------
@node       Display and Define the Metrics
@subsection Display and Define the Metrics
@c ----------------------------------------------------------------------------

The default metrics shown by @DisplayText{} are useful, but there is more
recorded than displayed. We can customize the values shown by defining the 
metrics ourselves.

@IndexSubentry{Commands, @code{metric_list}}
There are two commands related to changing the metrics shown: @code{metric_list}
and 
@IndexSubentry{Commands, @code{metrics}}
@code{metrics}.

The first command shows the metrics in use, plus all the metrics that have 
been stored as part of the experiment. The second command may be used to
define the metric list.

In our example we get the following values for the metrics:

@IndexSubentry{Commands, @code{metric_list}}
@cartouche
@smallexample
$ gprofng display text -metric_list test.1.er
@end smallexample
@end cartouche

@smallexample
@verbatim
Current metrics: e.totalcpu:i.totalcpu:name
Current Sort Metric: Exclusive Total CPU Time ( e.totalcpu )
Available metrics:
   Exclusive Total CPU Time: e.%totalcpu
   Inclusive Total CPU Time: i.%totalcpu
                       Size: size
                 PC Address: address
                       Name: name
@end verbatim
@end smallexample

This shows the metrics currently in use, the metric that is used to sort
the data and all the metrics that have been recorded, but are not necessarily
shown.

@cindex Default metrics
In this case, the default metrics are set to the exclusive and inclusive
total CPU times, plus the name of the function, or load object.

@IndexSubentry{Commands, @code{metrics}}
The @code{metrics} command is used to define the metrics that need to be
displayed. 

For example, to display the exclusive total CPU time, both as a number and a
percentage, use the following metric definition: @code{e.%totalcpu}

Since the metrics can be tailored for different views, there is a way
to reset them to the default. This is done through the special keyword
@code{default}.

@c -- A new node --------------------------------------------------------------
@node    A First Customization of the Output
@subsection A First Customization of the Output
@c ----------------------------------------------------------------------------

With the information just given, we can customize the function overview. 
For sake of the example, we would like to display the name of the function
first, followed by the exclusive CPU time, given as an absolute number and 
a percentage.

Note that the commands are parsed in order of appearance. This is why we
need to define the metrics @emph{before} requesting the function overview:

@cartouche
@smallexample
$ gprofng display text -metrics name:e.%totalcpu -functions test.1.er
@end smallexample
@end cartouche

@smallexample
@verbatim
Current metrics: name:e.%totalcpu
Current Sort Metric: Exclusive Total CPU Time ( e.%totalcpu )
Functions sorted by metric: Exclusive Total CPU Time

Name                Excl. Total
                    CPU
                     sec.      %
 <Total>            2.272 100.00
 mxv_core           2.160  95.04
 init_data          0.047   2.06
 erand48_r          0.030   1.32
 __drand48_iterate  0.013   0.57
 drand48            0.013   0.57
 _int_malloc        0.008   0.35
 brk                0.001   0.04
 sysmalloc          0.001   0.04
 __default_morecore 0.      0.
 __libc_start_main  0.      0.
 allocate_data      0.      0.
 collector_root     0.      0.
 driver_mxv         0.      0.
 main               0.      0.
 malloc             0.      0.
 sbrk               0.      0.
@end verbatim
@end smallexample

This was a first and simple example how to customize the output. Note that we
did not rerun our profiling job and merely modified the display settings.
Below we will show other and also more advanced examples of customization.


@c -- A new node --------------------------------------------------------------
@node    Name the Experiment Directory
@subsection Name the Experiment Directory
@c ----------------------------------------------------------------------------

When using @CollectApp{}, the default names for experiments work fine, but
they are quite generic. It is often more convenient to select a more 
descriptive name. For example, one that reflects conditions for the experiment 
conducted.

For this, the mutually exclusive @code{-o} and @code{-O} options come in handy. 
Both may be used to provide a name for the experiment directory, but the
behaviour of @CollectApp{} is different.

With the 
@IndexSubentry{Options, @code{-o}}
@code{-o} 
option, an existing experiment directory is not overwritten. You either
need to explicitly remove an existing directory first, or use a name that is not
in use yet.

This is in contrast with the behaviour for the
 @IndexSubentry{Options, @code{-O}}
@code{-O} 
option. Any existing (experiment) directory with the same name is silently 
overwritten.

Be aware that the name of the experiment directory has to end with @code{.er}.

@c -- A new node --------------------------------------------------------------
@node    Control the Number of Lines in the Output
@subsection Control the Number of Lines in the Output
@c ----------------------------------------------------------------------------

@IndexSubentry{Commands, @code{limit}}
The @code{limit <n>} command can be used to control the number of lines printed
in various overviews, including the function view, but it also takes effect
for other display commands, like @code{lines}.

The argument @code{<n>} should be a positive integer number. It sets the number
of lines in the function view. A value of zero resets the limit to the default.

Be aware that the pseudo-function @code{<Total>} counts as a regular function.
For example @code{limit 10} displays nine user level functions.

@c -- A new node --------------------------------------------------------------
@node    Sorting the Performance Data
@subsection Sorting the Performance Data
@c ----------------------------------------------------------------------------

@IndexSubentry{Commands, @code{sort}}
The @code{sort <key>} command sets the key to be used when sorting the 
performance data.

The key is a valid metric definition, but the
@cindex Visibility field
visibility field 
(@xref{Metric Definitions})
in the metric
definition is ignored since this does not affect the outcome of the sorting
operation.
For example if we set the sort key to @code{e.totalcpu}, the values
will be sorted in descending order with respect to the exclusive total
CPU time.

The data can be sorted in reverse order by prepending the metric definition
with a minus (@code{-}) sign. For example @code{sort -e.totalcpu}.

A default metric for the sort operation has been defined and since this is 
a persistent command, this default can be restored with @code{default} as 
the key.

@c -- A new node --------------------------------------------------------------
@node    Scripting
@subsection Scripting
@c ----------------------------------------------------------------------------

As is probably clear by now, the list with commands for @DisplayText{} can be
very long. This is tedious and also error prone. Luckily, there is an easier and 
more elegant way to control the behaviour of this tool.

@IndexSubentry{Commands, @code{script}}
Through the @code{script} command, the name of a file with commands can be
passed in. These commands are parsed and executed as if they appeared on
the command line in the same order as encountered in the file. The commands
in this script file can actually be mixed with commands on the command line.

The difference between the commands in the script file and those used on the
command line is that the latter require a leading dash (@code{-}) symbol.

Comment lines are supported. They need to start with the @code{#} symbol.

@c -- A new node --------------------------------------------------------------
@node       A More Elaborate Example
@subsection A More Elaborate Example
@c ----------------------------------------------------------------------------

With the information presented so far, we can customize our data
gathering and display commands.

As an example, to reflect the name of the algorithm and the number of threads 
that were used in the experiment, we select @code{mxv.1.thr.er} 
as the name of the experiment directory.
All we then need to 
do is to add the 
 @IndexSubentry{Options, @code{-O}}
@code{-O} 
option followed by this name on the command line when running @CollectApp{}:

@cartouche
@smallexample
$ exe=mxv-pthreads.exe
$ m=3000
$ n=2000
$ gprofng collect app -O mxv.1.thr.er ./$exe -m $m -n $n -t 1
@end smallexample
@end cartouche

The commands to generate the profile are put into a file that we simply call
@code{my-script}:

@smallexample
@verbatim
$ cat my-script
# This is my first gprofng script
# Set the metrics
metrics i.%totalcpu:e.%totalcpu:name
# Use the exclusive time to sort
sort e.totalcpu
# Limit the function list to 5 lines
limit 5
# Show the function list
functions
@end verbatim
@end smallexample

This script file is then specified as input to the @DisplayText{} command 
that is used to display the performance information stored in 
@code{mxv.1.thr.er}:

@cartouche
@smallexample
$ gprofng display text -script my-script mxv.1.thr.er
@end smallexample
@end cartouche

The command above produces the following output:

@smallexample
@verbatim
# This is my first gprofng script
# Set the metrics
Current metrics: i.%totalcpu:e.%totalcpu:name
Current Sort Metric: Exclusive Total CPU Time ( e.%totalcpu )
# Use the exclusive time to sort
Current Sort Metric: Exclusive Total CPU Time ( e.%totalcpu )
# Limit the function list to 5 lines
Print limit set to 5
# Show the function list
Functions sorted by metric: Exclusive Total CPU Time

Incl. Total   Excl. Total    Name
CPU           CPU
 sec.      %   sec.      %
2.272 100.00  2.272 100.00   <Total>
2.159  95.00  2.159  95.00   mxv_core
0.102   4.48  0.054   2.37   init_data
0.035   1.54  0.025   1.10   erand48_r
0.048   2.11  0.013   0.57   drand48
@end verbatim
@end smallexample

In the first part of the output, our comment lines in the script file are 
shown. These are interleaved with an acknowledgement message for the commands.

This is followed by a profile consisting of 5 lines only. For both metrics,
the percentages plus the timings are given. The numbers are sorted with respect 
to the exclusive total CPU time.

It is now immediately clear that function @code{mxv_core} is responsbile for
95% of the CPU time and @code{init_data} takes 4.5% only.

This is also where we see sampling in action. Although this is exactly the
same job we profiled before, the timings are somewhat different, but the
differences are very small.

@c -- A new node --------------------------------------------------------------
@node       The Call Tree
@subsection The Call Tree
@c ----------------------------------------------------------------------------

The call tree shows the dynamic hierarchy of the application by displaying the
functions executed and their parent. It helps to find the most expensive path
in the program.

@IndexSubentry{Commands, @code{calltree}}
This feature is enabled through the @code{calltree} command. This is how to get
this tree for our current experiment:

@cartouche
@smallexample
$ gprofng display text -calltree mxv.1.thr.er
@end smallexample
@end cartouche

This displays the following structure:

@smallexample
@verbatim
Functions Call Tree. Metric: Attributed Total CPU Time

Attr.      Name
Total
CPU sec.
2.272      +-<Total>
2.159        +-collector_root
2.159        |  +-driver_mxv
2.159        |    +-mxv_core
0.114        +-__libc_start_main
0.114          +-main
0.102            +-init_data
0.048            |  +-drand48
0.035            |    +-erand48_r
0.010            |      +-__drand48_iterate
0.011            +-allocate_data
0.011            |  +-malloc
0.011            |    +-_int_malloc
0.001            |      +-sysmalloc
0.001            +-check_results
0.001              +-malloc
0.001                +-_int_malloc
@end verbatim
@end smallexample

At first sight this may not be what you expected and some explanation is in
place.

@c ----------------------------------------------------------------------------
@c TBD: Revise this text when we have user and machine mode.
@c ----------------------------------------------------------------------------
First of all, function @code{collector_root} is internal to @ToolName{} and
should be hidden to the user. This is part of a planned future enhancement.

Recall that the @code{objects} and @code{fsingle} commands are very useful
to find out more about load objects in general, but also to help identify
an unknown entry in the function overview. @xref{Load Objects and Functions}.

Another thing to note is that there are two main branches. The one under
@code{collector_root} and the second one under @code{__libc_start_main}.
This reflects the fact that we are executing a parallel program. Even though
we only used one thread for this run, this is still executed in a separate
path.

The main, sequential part of the program is displayed under @code{main} and
shows the functions called and the time they took.

There are two things worth noting for the call tree feature:

@itemize

@item
This is a dynamic tree and since sampling is used, it most likely looks
slighlty different across seemingly identical profile runs. In case the
run times are short, it is worth considering to use a high resolution
through the 
@IndexSubentry{Options, @code{-p}}
@code{-p} 
option. For example to use @code{-p hi} to increase the sampling rate.

@item
In case hardware event counters have been enabled 
(@xref{Profile Hardware Event Counters}), these values are also displayed
in the call tree view.

@end itemize

@c -- A new node --------------------------------------------------------------
@node       More Information on the Experiment
@subsection More Information on the Experiment
@c ----------------------------------------------------------------------------

The experiment directory not only contains performance related data. Several
system characteristics, the actually command executed, and some global 
performance statistics can be displayed.

@IndexSubentry{Commands, @code{header}}
The @code{header} command displays information about the experiment(s).
For example, this is the command to extract this data from for our experiment 
directory:

@cartouche
@smallexample
$ gprofng display text -header mxv.1.thr.er
@end smallexample
@end cartouche

The above command prints the following information. Note that some of the
lay-out and the information has been modified. The textual changes are 
marked with the @code{<} and @code{>} symbols.

@smallexample
@verbatim
Experiment: mxv.1.thr.er
No errors
No warnings
Archive command `gp-archive -n -a on 
         --outfile <exp_dir>/archive.log <exp_dir>'

Target command (64-bit): './mxv-pthreads.exe -m 3000 -n 2000 -t 1'
Process pid 30591, ppid 30589, pgrp 30551, sid 30468
Current working directory: <cwd>
Collector version: `2.36.50'; experiment version 12.4 (64-bit)
Host `<hostname>', OS `Linux <version>', page size 4096, 
     architecture `x86_64'
  16 CPUs, clock speed 1995 MHz.
  Memory: 30871514 pages @  4096 = 120591 MB.
Data collection parameters:
  Clock-profiling, interval = 997 microsecs.
  Periodic sampling, 1 secs.
  Follow descendant processes from: fork|exec|combo

Experiment started <date and time>

Experiment Ended: 2.293162658
Data Collection Duration: 2.293162658
@end verbatim
@end smallexample

The output above may assist in troubleshooting, or to verify some of the
operational conditions and we recommand to include this command when 
generating a profile.

@IndexSubentry{Options, @code{-C}}
Related to this command there is a useful option to record your own comment(s) in 
an experiment.
To this end, use the @code{-C} option on the @CollectApp{} tool to
specify a comment string. Up to ten comment lines can be included. 
These comments are displayed with the @code{header} command on
the @DisplayText{} tool.

@IndexSubentry{Commands, @code{overview}}
The @code{overview} command displays information on the experiment(s) and also
shows a summary of the values for the metric(s) used. This is an example how to
use it on our newly created experiment directory:

@cartouche
@smallexample
$ gprofng display text -overview mxv.1.thr.er
@end smallexample
@end cartouche

@smallexample
@verbatim
Experiment(s):

Experiment      :mxv.1.thr.er
  Target        : './mxv-pthreads.exe -m 3000 -n 2000 -t 1'
  Host          : <hostname> (<ISA>, Linux <version>)
  Start Time    : <date and time>
  Duration      : 2.293 Seconds

Metrics:

  Experiment Duration (Seconds): [2.293]
  Clock Profiling
    [X]Total CPU Time - totalcpu (Seconds): [*2.272]

Notes: '*' indicates hot metrics, '[X]' indicates currently enabled 
       metrics.
       The metrics command can be used to change selections. The 
       metric_list command lists all available metrics.
@end verbatim
@end smallexample

This command provides a dashboard overview that helps to easily identify
where the time is spent and in case hardware event counters are used, it
shows their total values.

@c -- A new node --------------------------------------------------------------
@node       Control the Sampling Frequency
@subsection Control the Sampling Frequency
@c ----------------------------------------------------------------------------

So far we did not talk about the frequency of the sampling process, but in
some cases it is useful to change the default of 10 milliseconds.

The advantage of increasing the sampling frequency is that functions that
do not take much time per invocation are more accurately captured. The
downside is that more data is gathered. This has an impact on the overhead
of the collection process and more disk space is required. 

In general this is not an immediate concern, but with heavily threaded
applications that run for an extended period of time, increasing the 
frequency may have a more noticeable impact.

@IndexSubentry{Options, @code{-p}}
The @code{-p} option on the @CollectApp{} tool is used to enable or disable
clock based profiling, or to explicitly set the sampling rate. 
@cindex Sampling interval
This option takes one of the following keywords:

@table @code

@item off
Disable clock based profiling.

@item on
Enable clock based profiling with a per thread sampling interval of 10 ms. This is the default.

@item lo
Enable clock based profiling with a per thread sampling interval of 100 ms.

@item hi
Enable clock based profiling with a per thread sampling interval of 1 ms.

@item <value>
Enable clock based profiling with a per thread sampling interval of <value>. 

@end table 

One may wonder why there is an option to disable clock based profiling. This
is because by default, it is enabled when conducting hardware event counter
experiments (@xref{Profile Hardware Event Counters}).
With the @code{-p off} option, this can be disabled.

If an explicit value is set for the sampling, the number can be an integer or a 
floating-point number.
A  suffix of @code{u} for microseconds, or @code{m} for milliseconds is supported. 
If no suffix is used, the value is assumed to be in milliseconds.

If the value is smaller than the clock profiling minimum, a warning message is issued
and it is set to the minimum.
In case it is not a multiple of the clock profiling resolution, it is silently rounded 
down to the nearest multiple of the clock resolution. 

If the value exceeds the clock profiling maximum, is negative, or zero, an error is 
reported.

@IndexSubentry{Commands, @code{header}}
Note that the @code{header} command echoes the sampling rate used.

@c -- A new node --------------------------------------------------------------
@node    Information on Load Objects
@subsection Information on Load Objects
@c ----------------------------------------------------------------------------

It may happen that the function list contains a function that is not known to 
the user. This can easily happen with library functions for example.
Luckily there are three commands that come in handy then. 

@IndexSubentry{Commands, @code{objects}}
@IndexSubentry{Commands, @code{fsingle}}
@IndexSubentry{Commands, @code{fsummary}}
These commands are @code{objects}, @code{fsingle}, and @code{fsummary}. 
They provide details on
@cindex Load objects
load objects (@xref{Load Objects and Functions}).

The @code{objects} command lists all load objects that have been referenced 
during the performance experiment.
Below we show the command and the result for our profile job. Like before, 
the (long) path names in the output have been shortened and replaced by the 
@IndexSubentry{Miscellaneous, @code{<apath>}}
@code{<apath>} symbol that represents an absolute directory path.

@cartouche
@smallexample
$ gprofng display text -objects mxv.1.thr.er
@end smallexample
@end cartouche

The output includes the name and path of the target executable:

@smallexample
@verbatim
 <Unknown> (<Unknown>)
 <mxv-pthreads.exe> (<apath>/mxv-pthreads.exe)
 <librt-2.17.so> (/usr/lib64/librt-2.17.so)
 <libdl-2.17.so> (/usr/lib64/libdl-2.17.so)
 <libbfd-2.36.50.20210505.so> (<apath>/libbfd-2.36.50 <etc>)
 <libopcodes-2.36.50.20210505.so> (<apath>/libopcodes-2. <etc>)
 <libc-2.17.so> (/usr/lib64/libc-2.17.so)
 <libpthread-2.17.so> (/usr/lib64/libpthread-2.17.so)
 <libm-2.17.so> (/usr/lib64/libm-2.17.so)
 <libgp-collector.so> (<apath>/libgp-collector.so)
 <ld-2.17.so> (/usr/lib64/ld-2.17.so)
 <DYNAMIC_FUNCTIONS> (DYNAMIC_FUNCTIONS)
@end verbatim
@end smallexample

@IndexSubentry{Commands, @code{fsingle}}
The @code{fsingle} command may be used to get more details on a specific entry 
in the function view, say. For example, the command below provides additional
information on the @code{collector_root} function shown in the function overview.

@cartouche
@smallexample
$ gprofng display text -fsingle collector_root mxv.1.thr.er
@end smallexample
@end cartouche

Below the output from this command. It has been somewhat modified to match the
display requirements.

@smallexample
@verbatim
collector_root
  Exclusive Total CPU Time: 0.    (  0. %)
  Inclusive Total CPU Time: 2.159 ( 95.0%)
            Size:   401
      PC Address: 10:0x0001db60
     Source File: <apath>/dispatcher.c
     Object File: mxv.1.thr.er/archives/libgp-collector.so_HpzZ6wMR-3b
     Load Object: <apath>/libgp-collector.so
    Mangled Name:
         Aliases:
@end verbatim
@end smallexample

In this table we not only see how much time was spent in this function, we
also see where it originates from. In addition to this, the size and start
address are given as well. If the source code location is known it is also 
shown here.

@IndexSubentry{Commands, @code{fsummary}}
The related @code{fsummary} command displays the same information as 
@code{fsingle}, but for all functions in the function overview, 
including @code{<Total>}:

@cartouche
@smallexample
$ gprofng display text -fsummary mxv.1.thr.er
@end smallexample
@end cartouche

@smallexample
@verbatim
Functions sorted by metric: Exclusive Total CPU Time

<Total>
  Exclusive Total CPU Time: 2.272 (100.0%)
  Inclusive Total CPU Time: 2.272 (100.0%)
            Size:     0
      PC Address: 1:0x00000000
     Source File: (unknown)
     Object File: (unknown)
     Load Object: <Total>
    Mangled Name:
         Aliases:

mxv_core
  Exclusive Total CPU Time: 2.159 ( 95.0%)
  Inclusive Total CPU Time: 2.159 ( 95.0%)
            Size:    75
      PC Address: 2:0x000021ba
     Source File: <apath>/mxv.c
     Object File: mxv.1.thr.er/archives/mxv-pthreads.exe_hRxWdccbJPc
     Load Object: <apath>/mxv-pthreads.exe
    Mangled Name:
         Aliases:

          ... etc ...
@end verbatim
@end smallexample

@c -- A new node --------------------------------------------------------------
@node    Support for Multithreading
@section Support for Multithreading
@c ----------------------------------------------------------------------------

In this chapter we introduce and discuss the support for multithreading. As
is shown below, nothing needs to be changed when collecting the performance 
data.

The difference is that additional commands are available to get more 
information on the parallel environment, plus that several filters allow
the user to zoom in on specific threads.

@c -- A new node --------------------------------------------------------------
@node       Creating a Multithreading Experiment
@subsection Creating a Multithreading Experiment
@c ----------------------------------------------------------------------------

We demonstrate the support for multithreading using the same code and settings
as before, but this time we use 2 threads:

@cartouche
@smallexample
$ exe=mxv-pthreads.exe
$ m=3000
$ n=2000
$ gprofng collect app -O mxv.2.thr.er ./$exe -m $m -n $n -t 2
@end smallexample
@end cartouche

First of all, note that we did not change anything, other than setting the 
number of threads to 2. Nothing special is needed to profile a multithreaded
job when using @ToolName{}.

The same is true when displaying the performance results. The same commands
that we used before work unmodified. For example, this is all that is needed to 
get a function overview:

@cartouche
@smallexample
$ gpprofng display text -limit 10 -functions mxv.2.thr.er
@end smallexample
@end cartouche

This produces the following familiar looking output:

@smallexample
@verbatim
Print limit set to 10
Functions sorted by metric: Exclusive Total CPU Time

Excl.     Incl.      Name
Total     Total
CPU sec.  CPU sec.
2.268     2.268      <Total>
2.155     2.155      mxv_core
0.044     0.103      init_data
0.030     0.046      erand48_r
0.016     0.016      __drand48_iterate
0.013     0.059      drand48
0.008     0.011      _int_malloc
0.003     0.003      brk
0.        0.003      __default_morecore
0.        0.114      __libc_start_main
@end verbatim
@end smallexample

@c -- A new node --------------------------------------------------------------
@node       Commands Specific to Multithreading
@subsection Commands Specific to Multithreading
@c ----------------------------------------------------------------------------

The function overview shown above shows the results aggregated over all the 
threads. The interesting new element is that we can also look at the 
performance data for the individual threads.

@IndexSubentry{Commands, @code{thread_list}}
The @code{thread_list} command displays how many threads have been used:

@cartouche
@smallexample
$ gprofng display text -thread_list mxv.2.thr.er
@end smallexample
@end cartouche

This produces the following output, showing that three threads have
been used:

@smallexample
@verbatim
Exp Sel Total
=== === =====
  1 all     3
@end verbatim
@end smallexample

The output confirms there is one experiment and that by default all
threads are selected.

It may seem surprising to see three threads here, since we used the 
@code{-t 2} option, but it is common for a Pthreads program to use one 
additional thread. This is typically the thread that runs from start to 
finish and handles the sequential portions of the code, as well as takes
care of managing the threads. 

It is no different in our example code. At some point, the main thread 
creates and activates the two threads that perform the multiplication 
of the matrix with the vector. Upon completion of this computation,
the main thread continues.

@IndexSubentry{Commands, @code{threads}}
The @code{threads} command is simple, yet very powerful. It shows the
total value of the metrics for each thread. To make it easier to 
interpret the data, we modify the metrics to include percentages:

@cartouche
@smallexample
$ gprofng display text -metrics e.%totalcpu -threads mxv.2.thr.er
@end smallexample
@end cartouche

The command above produces the following overview:

@smallexample
@verbatim
Current metrics: e.%totalcpu:name
Current Sort Metric: Exclusive Total CPU Time ( e.%totalcpu )
Objects sorted by metric: Exclusive Total CPU Time

Excl. Total    Name
CPU
 sec.      %
2.258 100.00   <Total>
1.075  47.59   Process 1, Thread 3
1.070  47.37   Process 1, Thread 2
0.114   5.03   Process 1, Thread 1
@end verbatim
@end smallexample

The first line gives the total CPU time accumulated over the threads
selected. This is followed by the metric value(s) for each thread.

From this it is clear that the main thread is responsible for 5% of
the total CPU time, while the other two threads take 47% each.

This view is ideally suited to verify if there any load balancing
issues and also to find the most time consuming thread(s).

@IndexSubentry{Filters, Thread selection}
While useful, often more information than this is needed. This is
@IndexSubentry{Commands, @code{thread_select}}
where the thread selection filter comes in. Through the @code{thread_select}
command, one or more threads may be selected 
(@xref{The Selection List} how to define the selection list).

Since it is most common to use this command in a script, we do so as
well here. Below the script we are using:

@cartouche
@smallexample
# Define the metrics
metrics e.%totalcpu
# Limit the output to 10 lines
limit 10
# Get the function overview for thread 1
thread_select 1
functions
# Get the function overview for thread 2
thread_select 2
functions
# Get the function overview for thread 3
thread_select 3
functions
@end smallexample
@end cartouche

The definition of the metrics and the output limiter has been shown and
explained before and will be ignored. The new command we focus on is 
@IndexSubentry{Commands, @code{thread_select}}
@code{thread_select}.

This command takes a list (@xref{The Selection List}) to select specific
threads. In this case we simply use the individual thread numbers that we
obtained with the @code{thread_list} command earlier.

This restricts the output of the @code{functions} command to the thread
number(s) specified. This means that the script above shows which 
function(s) each thread executes and how much CPU time they consumed.
Both the timings and their percentages are given.

This is the relevant part of the output for the first thread:

@smallexample
@verbatim
# Get the function overview for thread 1
Exp Sel Total
=== === =====
  1 1       3
Functions sorted by metric: Exclusive Total CPU Time

Excl. Total    Name
CPU
 sec.      %
0.114 100.00   <Total>
0.051  44.74   init_data
0.028  24.56   erand48_r
0.017  14.91   __drand48_iterate
0.010   8.77   _int_malloc
0.008   7.02   drand48
0.      0.     __libc_start_main
0.      0.     allocate_data
0.      0.     main
0.      0.     malloc
@end verbatim
@end smallexample

As usual, the comment lines are echoed. This is followed by a confirmation
of our selection. We see that indeed thread 1 has been selected. What is
displayed next is the function overview for this particular thread. Due to
the @code{limit 10} command, there are ten entries in this list.

Below are the overviews for threads 2 and 3 respectively. We see that all
of the CPU time is spent in function @code{mxv_core} and that this time
is approximately the same for both threads.

@smallexample
@verbatim
# Get the function overview for thread 2
Exp Sel Total
=== === =====
  1 2       3
Functions sorted by metric: Exclusive Total CPU Time

Excl. Total    Name
CPU
 sec.      %
1.072 100.00   <Total>
1.072 100.00   mxv_core
0.      0.     collector_root
0.      0.     driver_mxv

# Get the function overview for thread 3
Exp Sel Total
=== === =====
  1 3       3
Functions sorted by metric: Exclusive Total CPU Time

Excl. Total    Name
CPU
 sec.      %
1.076 100.00   <Total>
1.076 100.00   mxv_core
0.      0.     collector_root
0.      0.     driver_mxv
@end verbatim
@end smallexample

When analyzing the performance of a multithreaded application, it is sometimes
useful to know whether threads have mostly executed on the same core, say, or
if they have wandered across multiple cores. This sort of stickiness is usually 
referred to as
@cindex Thread affinity
@emph{thread affinity}.

Similar to the commands for the threads, there are several commands related 
to the usage of the cores, or @emph{CPUs} as they are called in @ToolName{}
(@xref{The Concept of a CPU in @ProductName{}}).

In order to have some more interesting data to look at, we created a new
experiment, this time using 8 threads:

@cartouche
@smallexample
$ exe=mxv-pthreads.exe
$ m=3000
$ n=2000
$ gprofng collect app -O mxv.8.thr.er ./$exe -m $m -n $n -t 8
@end smallexample
@end cartouche

@IndexSubentry{Commands, @code{cpu_list}}
Similar to the @code{thread_list} command, the @code{cpu_list} command 
displays how many CPUs have been used. 
@IndexSubentry{Commands, @code{cpus}}
The equivalent of the @code{threads} threads command, is the @code{cpus} 
command, which shows the CPU numbers that were used and how much time was 
spent on each of them. Both are demonstrated below.

@cartouche
@smallexample
$ gprofng display text -metrics e.%totalcpu -cpu_list -cpus mxv.8.thr.er
@end smallexample
@end cartouche

This command produces the following output:

@smallexample
@verbatim
Current metrics: e.%totalcpu:name
Current Sort Metric: Exclusive Total CPU Time ( e.%totalcpu )
Exp Sel Total
=== === =====
  1 all    10
Objects sorted by metric: Exclusive Total CPU Time

Excl. Total    Name
CPU
 sec.      %
2.310 100.00   <Total>
0.286  12.39   CPU 7
0.284  12.30   CPU 13
0.282  12.21   CPU 5
0.280  12.13   CPU 14
0.266  11.52   CPU 9
0.265  11.48   CPU 2
0.264  11.44   CPU 11
0.194   8.42   CPU 0
0.114   4.92   CPU 1
0.074   3.19   CPU 15
@end verbatim
@end smallexample

@c ----------------------------------------------------------------------------
@c TBD - Ruud
@c I'd like to improve this and have a way to see where a thread has executed.
@c ----------------------------------------------------------------------------

What we see in this table is that a total of 10 CPUs have been used. This is
followed by a list with all the CPU numbers that have been used during the 
run. For each CPU it is shown how much time was spent on it.

While the table with thread times shown earlier may point at a load imbalance
in the application, this overview has a different purpose.

For example, we see that 10 CPUs have been used, but we know that the 
application uses 9 threads only.
This means that at least one thread has executed on more than one CPU. In 
itself this is not something to worry about, but warrants a deeper 
investigation.

Honesty dictates that next we performed a pre-analysis to find out 
which thread(s) have been running on more than one CPU. We found this 
to be thread 7. It has executed on CPUs 0 and 15.

With this knowledge, we wrote the script shown below. It zooms in on
the behaviour of thread 7.

@cartouche
@smallexample
# Define the metrics
metrics e.%totalcpu
# Limit the output to 10 lines
limit 10
functions
# Get the function overview for CPU 0
cpu_select 0
functions
# Get the function overview for CPU 15
cpu_select 15
functions
@end smallexample
@end cartouche

From the earlier shown threads overview, we know that thread 7 has
used @code{0.268} seconds of CPU time..

By selecting CPUs 0 and 15, respectively, we get the following
function overviews:

@smallexample
@verbatim
# Get the function overview for CPU 0
Exp Sel Total
=== === =====
  1 0      10
Functions sorted by metric: Exclusive Total CPU Time

Excl. Total    Name
CPU
 sec.      %
0.194 100.00   <Total>
0.194 100.00   mxv_core
0.      0.     collector_root
0.      0.     driver_mxv

# Get the function overview for CPU 15
Exp Sel Total
=== === =====
  1 15     10
Functions sorted by metric: Exclusive Total CPU Time

Excl. Total    Name
CPU
 sec.      %
0.074 100.00   <Total>
0.074 100.00   mxv_core
0.      0.     collector_root
0.      0.     driver_mxv
@end verbatim
@end smallexample

This shows that thread 7 spent @code{0.194} seconds on CPU 0 and 
@code{0.074} seconds on CPU 15.

@c -- A new node --------------------------------------------------------------
@node    Viewing Multiple Experiments
@section Viewing Multiple Experiments
@c ----------------------------------------------------------------------------

One thing we did not cover sofar is that @ToolName{} fully supports the analysis
of multiple experiments. The @DisplayText{} tool accepts a list of experiments.
The data can either be aggregated across the experiments, or used in a 
comparison.

Mention @code{experiment_list}

@c -- A new node --------------------------------------------------------------
@node    Aggregation of Experiments
@subsection Aggregation of Experiments
@c ----------------------------------------------------------------------------

By default, the data for multiple experiments is aggregrated and the display 
commands shows these combined results.

For example, we can aggregate the data for our single and dual thread
experiments. Below is the script we used for this:

@cartouche
@smallexample
# Define the metrics
metrics e.%totalcpu
# Limit the output to 10 lines
limit 10
# Get the list with experiments
experiment_list
# Get the function overview
functions
@end smallexample
@end cartouche

@IndexSubentry{Commands, @code{experiment_list}}
With the exception of the @code{experiment_list} command, all commands
used have been discussed earlier.

The @code{experiment_list} command provides a list of the experiments
that have been loaded. This is is used to verify we are looking at the
experiments we intend to aggregate.

@cartouche
@smallexample
$ gprofng display text -script my-script-agg mxv.1.thr.er mxv.2.thr.er
@end smallexample
@end cartouche

With the command above, we get the following output:

@smallexample
@verbatim
# Define the metrics
Current metrics: e.%totalcpu:name
Current Sort Metric: Exclusive Total CPU Time ( e.%totalcpu )
# Limit the output to 10 lines
Print limit set to 10
# Get the list with experiments
ID Sel   PID Experiment
== === ===== ============
 1 yes 30591 mxv.1.thr.er
 2 yes 11629 mxv.2.thr.er
# Get the function overview
Functions sorted by metric: Exclusive Total CPU Time

Excl. Total    Name
CPU
 sec.      %
4.533 100.00   <Total>
4.306  94.99   mxv_core
0.105   2.31   init_data
0.053   1.17   erand48_r
0.027   0.59   __drand48_iterate
0.021   0.46   _int_malloc
0.021   0.46   drand48
0.001   0.02   sysmalloc
0.      0.     __libc_start_main
0.      0.     allocate_data
@end verbatim
@end smallexample

The first five lines should look familiar. The five lines following, echo
the comment line in the script and show the overview of the experiments.
This confirms two experiments have been loaded and that both are active.

This is followed by the function overview. The timings have been summed
up and the percentages are adjusted accordingly. For example, the total
accumulated time is indeed 2.272 + 2.261 = 4.533 seconds.

@c -- A new node --------------------------------------------------------------
@node       Comparison of Experiments
@subsection Comparison of Experiments
@c ----------------------------------------------------------------------------

The support for multiple experiments really shines in comparison mode. This
feature is enabled through the command 
@IndexSubentry{Commands, @code{compare on/off}}
@code{compare on} 
and is disabled
by setting 
@code{compare off}.

@cindex Compare experiments
In comparison mode, the data for the various experiments is shown side by
side, as illustrated below where we compare the results for the multithreaded
experiments using one and two threads respectively:

@cartouche
@smallexample
$ gprofng display text -compare on -functions mxv.1.thr.er mxv.2.thr.er
@end smallexample
@end cartouche

@noindent
This produces the following output:

@smallexample
@verbatim
Functions sorted by metric: Exclusive Total CPU Time

mxv.1.thr.er  mxv.2.thr.er  mxv.1.thr.er  mxv.2.thr.er
Excl. Total   Excl. Total   Incl. Total   Incl. Total    Name
CPU           CPU           CPU           CPU
 sec.          sec.          sec.          sec.
2.272         2.261         2.272         2.261          <Total>
2.159         2.148         2.159         2.148          mxv_core
0.054         0.051         0.102         0.104          init_data
0.025         0.028         0.035         0.045          erand48_r
0.013         0.008         0.048         0.053          drand48
0.011         0.010         0.012         0.010          _int_malloc
0.010         0.017         0.010         0.017          __drand48_iterate
0.001         0.            0.001         0.             sysmalloc
0.            0.            0.114         0.114          __libc_start_main
0.            0.            0.011         0.010          allocate_data
0.            0.            0.001         0.             check_results
0.            0.            2.159         2.148          collector_root
0.            0.            2.159         2.148          driver_mxv
0.            0.            0.114         0.114          main
0.            0.            0.012         0.010          malloc
@end verbatim
@end smallexample

This table is already helpful to more easily compare (two) profiles, but 
there is more that we can do here. 

By default, in comparison mode, all measured values are shown. Often 
profiling is about comparing performance data. It is therefore
more useful to look at differences, or ratios, using one experiment as 
a reference. 

The values shown are relative to this difference. For example if a ratio
is below one, it means the reference value was higher. 

@IndexSubentry{Commands, @code{compare on/off}}
This feature is supported on the @code{compare} command. In addition to @code{on},
or @code{off}, this command also supports 
@IndexSubentry{Commands, @code{compare delta}}
@code{delta}, or 
@IndexSubentry{Commands, @code{compare ratio}}
@code{ratio}.

Usage of one of these two keywords enables the comparison feature and shows
either the difference, or the ratio, relative to the reference data.

In the example below, we use the same two experiments used in the comparison
above, but as before, the number of lines is restricted to 10 and we focus on 
the exclusive timings plus percentages. For the comparison part we are 
interested in the differences.

This is the script that produces such an overview:

@cartouche
@smallexample
# Define the metrics
metrics e.%totalcpu
# Limit the output to 10 lines
limit 10
# Set the comparison mode to differences
compare delta
# Get the function overview
functions
@end smallexample
@end cartouche

Assuming this script file is called @code{my-script-comp}, this is how we
get the table displayed on our screen:

@cartouche
@smallexample
$ gprofng display text -script my-script-comp mxv.1.thr.er mxv.2.thr.er
@end smallexample
@end cartouche

Leaving out some of the lines printed, but we have seen before, we get 
the following table:

@smallexample
@verbatim
mxv.1.thr.er  mxv.2.thr.er
Excl. Total   Excl. Total     Name
CPU           CPU
 sec.      %   delta      %
2.272 100.00  -0.011 100.00   <Total>
2.159  95.00  -0.011  94.97   mxv_core
0.054   2.37  -0.003   2.25   init_data
0.025   1.10  +0.003   1.23   erand48_r
0.013   0.57  -0.005   0.35   drand48
0.011   0.48  -0.001   0.44   _int_malloc
0.010   0.44  +0.007   0.75   __drand48_iterate
0.001   0.04  -0.001   0.     sysmalloc
0.      0.    +0.      0.     __libc_start_main
0.      0.    +0.      0.     allocate_data
@end verbatim
@end smallexample

It is now easy to see that the CPU times for the most time consuming
functions in this code are practically the same. 

While in this case we used the delta as a comparison,

Note that the comparison feature is supported at the function, source, and 
disassembly level. There is no practical limit on the number of experiments
that can be used in a comparison.



@c -- A new node --------------------------------------------------------------
@node    Profile Hardware Event Counters
@section Profile Hardware Event Counters
@c ----------------------------------------------------------------------------

Many processors provide a set of hardware event counters and @ToolName{}
provides support for this feature.
@xref{Hardware Event Counters Explained} for those readers that are not 
familiar with such counters and like to learn more.

In this section we explain how to get the details on the event counter
support for the processor used in the experiment(s), and show several
examples.

@c -- A new node --------------------------------------------------------------
@node       Getting Information on the Counters Supported
@subsection Getting Information on the Counters Supported
@c ----------------------------------------------------------------------------

The first step is to check if the processor used for the experiments is 
supported by @ToolName{}.

@IndexSubentry{Options, @code{-h}}
The @code{-h} option on @CollectApp{} will show the event counter
information:

@cartouche
@smallexample
$ gprofng collect app -h
@end smallexample
@end cartouche

In case the counters are supported, a list with the events is printed. 
Otherwise, a warning message will be issued. 

For example, below we show this command and the output on an Intel Xeon 
Platinum 8167M (aka ``Skylake'') processor. The output has been split
into several sections and each section is commented upon separately.

@smallexample
@verbatim
Run "gprofng collect app --help" for a usage message.

Specifying HW counters on `Intel Arch PerfMon v2 on Family 6 Model 85' 
(cpuver=2499):

  -h {auto|lo|on|hi}
	turn on default set of HW counters at the specified rate
  -h <ctr_def> [-h <ctr_def>]...
  -h <ctr_def>[,<ctr_def>]...
	specify HW counter profiling for up to 4 HW counters
@end verbatim
@end smallexample

The first line shows how to get a usage overview. This is followed by
some information on the target processor.

The next five lines explain in what ways the @code{-h} option can be 
used to define the events to be monitored.

The first version shown above enables a default set of counters. This
default depends on the processor this command is executed on. The
keyword following the @code{-h} option defines the sampling rate:

@table @code

@item auto
Match the sample rate of used by clock profiling. If the latter is disabled,
Use a per thread sampling rate of approximately 100 samples per second.
This setting is the default and preferred.

@item on
Use a per thread sampling rate of approximately 100 samples per second.

@item lo
Use a per thread sampling rate of approximately 10 samples per second.

@item hi
Use a per thread sampling rate of approximately 1000 samples per second.

@end table 

The second and third variant define the events to be monitored. Note
that the number of simultaneous events supported is printed. In this
case we can monitor four events in a single profiling job.

It is a matter of preference whether you like to use the @code{-h}
option for each event, or use it once, followed by a comma separated
list.

There is one slight catch though. The counter definition below has 
mandatory comma (@code{,}) between the event and the rate. While a 
default can be used for the rate, the comma cannot be omitted. 
This may result in a somewhat awkward counter definition in case
the default sampling rate is used.

For example, the following two commands are equivalent. Note
the double comma in the second command. This is not a typo.

@cartouche
@smallexample
$ gprofng collect app -h cycles -h insts ... 
$ gprofng collect app -h cycles,,insts ... 
@end smallexample
@end cartouche

In the first command this comma is not needed, because a 
comma (``@code{,}'') immediately followed by white space may 
be omitted.

This is why we prefer the this syntax and in the remainder will 
use the first version of this command.

@IndexSubentry{Hardware event counters, counter definition}
The counter definition takes an event name, plus optionally one or
more attributes, followed by a comma, and optionally the sampling rate.
The output section below shows the formal definition.

@cartouche
@smallexample
  <ctr_def> == <ctr>[[~<attr>=<val>]...],[<rate>]
@end smallexample
@end cartouche

The printed help then explains this syntax. Below we have summarized
and expanded this output:

@table @code

@item <ctr>
The counter name must be selected from the available counters listed
as part of the output printed with the @code{-h} option.
On most systems, if a counter is not listed, it may still be specified 
by its numeric value.

@item ~<attr>=<val>
This is an optional attribute that depends on the processor. The list
of supported attributes is printed in the output. Examples of 
attributes are ``user'', or ``system''. The value can given in decimal
or hexadecimal format.
Multiple attributes may be specified, and each must be preceded 
by a ~.

@item <rate>

The sampling rate is one of the following:

@table @code

@item auto
This is the default and matches the rate used by clock profiling.
If clock profiling is disabled, use @code{on}.

@item on
Set the per thread maximum sampling rate to ~100 samples/second

@item lo
Set the per thread maximum sampling rate to ~10 samples/second

@item hi
Set the per thread maximum sampling rate to ~1000 samples/second

@item <interval>
Define the sampling interval. 
@xref{Control the Sampling Frequency} how to define this.

@end table

@end table

After the section with the formal definition of events and counters, a
processor specific list is displayed. This part starts with an overview
of the default set of counters and the aliased names supported 
@emph{on this specific processor}.

@smallexample
@verbatim
Default set of HW counters:

    -h cycles,,insts,,llm

Aliases for most useful HW counters:

 alias    raw name                   type units regs description

 cycles   unhalted-core-cycles   CPU-cycles 0123 CPU Cycles
 insts    instruction-retired        events 0123 Instructions Executed
 llm      llc-misses                 events 0123 Last-Level Cache Misses
 br_msp   branch-misses-retired      events 0123 Branch Mispredict
 br_ins   branch-instruction-retired events 0123 Branch Instructions
@end verbatim
@end smallexample

The definitions given above may or may not be available on other processors,
but we try to maximize the overlap across alias sets.

The table above shows the default set of counters defined for this processor,
and the aliases. For each alias the full ``raw'' name is given, plus the
unit of the number returned by the counter (CPU cycles, or a raw count), 
the hardware counter the event is allowed to be mapped onto, and a short 
description.

The last part of the output contains all the events that can be monitored:

@smallexample
@verbatim
Raw HW counters:

    name                                type      units regs description

    unhalted-core-cycles                     CPU-cycles 0123
    unhalted-reference-cycles                    events 0123
    instruction-retired                          events 0123
    llc-reference                                events 0123
    llc-misses                                   events 0123
    branch-instruction-retired                   events 0123
    branch-misses-retired                        events 0123
    ld_blocks.store_forward                      events 0123
    ld_blocks.no_sr                              events 0123
    ld_blocks_partial.address_alias              events 0123
    dtlb_load_misses.miss_causes_a_walk          events 0123
    dtlb_load_misses.walk_completed_4k           events 0123

    <many lines deleted>

    l2_lines_out.silent                          events 0123
    l2_lines_out.non_silent                      events 0123
    l2_lines_out.useless_hwpf                    events 0123
    sq_misc.split_lock                           events 0123

See Chapter 19 of the "Intel 64 and IA-32 Architectures Software
Developer's Manual Volume 3B: System Programming Guide"
@end verbatim
@end smallexample

As can be seen, these names are not always easy to correlate to a specific
event of interest. The processor manual should provide more clarity on this.

@c -- A new node --------------------------------------------------------------
@node       Examples Using Hardware Event Counters
@subsection Examples Using Hardware Event Counters
@c ----------------------------------------------------------------------------

The previous section may give the impression that these counters are hard to
use, but as we will show now, in practice it is quite simple.

With the information from the @code{-h} option, we can easily set up our first 
event counter experiment.

We start by using the default set of counters defined for our processor and we
use 2 threads:

@cartouche
@smallexample
$ exe=mxv-pthreads.exe
$ m=3000
$ n=2000
$ exp=mxv.hwc.def.2.thr.er
$ gprofng collect app -O $exp -h auto ./$exe -m $m -n $n -t 2
@end smallexample
@end cartouche

@IndexSubentry{Options, @code{-h}}
@IndexSubentry{Hardware event counters, @code{auto} option}
The new option here is @code{-h auto}. The @code{auto} keyword enables 
hardware event counter profiling and selects the default set of counters 
defined for this processor.

As before, we can display the information, but there is one practical hurdle
to take. Unless we like to view all metrics recorded, we would need to know
the names of the events that have been enabled. This is tedious and also not
portable in case we would like to repeat this experiment on another processor.

@IndexSubentry{Hardware event counters, @code{hwc} metric}
This is where the special @code{hwc} metric comes very handy. It 
automatically expands to the active set of events used.

With this, it is very easy to display the event counter values. Note that
although the regular clock based profiling was enabled, we only want to see 
the counter values. We also request to see the percentages and limit the
output to the first 5 lines:

@cartouche
@smallexample
$ exp=mxv.hwc.def.2.thr.er
$ gprofng display text -metrics e.%hwc -limit 5 -functions $exp
@end smallexample
@end cartouche

@smallexample
@verbatim
Current metrics: e.%cycles:e+%insts:e+%llm:name
Current Sort Metric: Exclusive CPU Cycles ( e.%cycles )
Print limit set to 5
Functions sorted by metric: Exclusive CPU Cycles

Excl. CPU     Excl. Instructions  Excl. Last-Level   Name
Cycles        Executed            Cache Misses
 sec.      %                  %                 %
2.691 100.00  7906475309 100.00   122658983 100.00   <Total>
2.598  96.54  7432724378  94.01   121745696  99.26   mxv_core
0.035   1.31   188860269   2.39       70084   0.06   erand48_r
0.026   0.95    73623396   0.93      763116   0.62   init_data
0.018   0.66    76824434   0.97       40040   0.03   drand48
@end verbatim
@end smallexample

As we have seen before, the first few lines echo the settings.
This includes a list with the hardware event counters used by
default.

The table that follows makes it very easy to get an overview where the 
time is spent and how many of the target events have occurred.

As before, we can drill down deeper and see the same metrics at the source
line and instruction level. Other than using @code{hwc} in the metrics
definitions, nothing has changed compared to the previous examples:

@cartouche
@smallexample
$ exp=mxv.hwc.def.2.thr.er
$ gprofng display text -metrics e.hwc -source mxv_core $exp
@end smallexample
@end cartouche

This is the relevant part of the output. Since the lines get very long,
we have somewhat modified the lay-out:

@smallexample
@verbatim
   Excl. CPU Excl.        Excl.
   Cycles    Instructions Last-Level
    sec.     Executed     Cache Misses
                                         <Function: mxv_core>
   0.                 0          0   32. void __attribute__ ((noinline)) 
                                         mxv_core(...)
   0.                 0          0   33. {
   0.                 0          0   34.   for (uint64_t i=...) {
   0.                 0          0   35.     double row_sum = 0.0;
## 1.872     7291879319   88150571   36.     for (int64_t j=0; j<n; j++)
   0.725      140845059   33595125   37.        row_sum += A[i][j]*b[j];
   0.                 0          0   38.     c[i] = row_sum;
                                     39.    }
   0.                 0          0   40. }
@end verbatim
@end smallexample

In a smiliar way we can display the event counter values at the instruction
level. Again we have modified the lay-out due to page width limitations:

@cartouche
@smallexample
$ exp=mxv.hwc.def.2.thr.er
$ gprofng display text -metrics e.hwc -disasm mxv_core $exp
@end smallexample
@end cartouche

@smallexample
@verbatim
   Excl. CPU Excl.        Excl.
   Cycles    Instructions Last-Level
    sec.     Executed     Cache Misses
                                                <Function: mxv_core>
   0.                 0          0  [33] 4021ba: mov   0x8(%rsp),%r10
                                    34.   for (uint64_t i=...) {
   0.                 0          0  [34] 4021bf: cmp   %rsi,%rdi
   0.                 0          0  [34] 4021c2: jbe   0x37
   0.                 0          0  [34] 4021c4: ret
                                    35.       double row_sum = 0.0;
                                    36.       for (int64_t j=0; j<n; j++)
                                    37.         row_sum += A[i][j]*b[j];
   0.                 0          0  [37] 4021c5: mov   (%r8,%rdi,8),%rdx
   0.                 0          0  [36] 4021c9: mov   $0x0,%eax
   0.                 0          0  [35] 4021ce: pxor  %xmm1,%xmm1
   0.002       12804230     321394  [37] 4021d2: movsd (%rdx,%rax,8),%xmm0
   0.141       60819025    3866677  [37] 4021d7: mulsd (%r9,%rax,8),%xmm0
   0.582       67221804   29407054  [37] 4021dd: addsd %xmm0,%xmm1
## 1.871     7279075109   87989870  [36] 4021e1: add   $0x1,%rax
   0.002       12804210      80351  [36] 4021e5: cmp   %rax,%rcx
   0.                 0          0  [36] 4021e8: jne   0xffffffffffffffea
                                    38.       c[i] = row_sum;
   0.                 0          0  [38] 4021ea: movsd %xmm1,(%r10,%rdi,8)
   0.                 0          0  [34] 4021f0: add   $0x1,%rdi
   0.                 0          0  [34] 4021f4: cmp   %rdi,%rsi
   0.                 0          0  [34] 4021f7: jb    0xd
   0.                 0          0  [35] 4021f9: pxor  %xmm1,%xmm1
   0.                 0          0  [36] 4021fd: test  %rcx,%rcx
   0.                 0      80350  [36] 402200: jne   0xffffffffffffffc5
   0.                 0          0  [36] 402202: jmp   0xffffffffffffffe8
                                    39.   }
                                    40. }
   0.                 0          0  [40]  402204:  ret
@end verbatim
@end smallexample

So far we have used the default settings for the event counters. It is
quite straightforward to select specific counters. For sake of the
example, let's assume we would like to count how many branch instructions
and retired memory load instructions that missed in the L1 cache have been
executed. We also want to count these events with a high resolution.

This is the command to do so:

@cartouche
@smallexample
$ exe=mxv-pthreads.exe
$ m=3000
$ n=2000
$ exp=mxv.hwc.sel.2.thr.er
$ hwc1=br_ins,hi
$ hwc2=mem_load_retired.l1_miss,hi
$ gprofng collect app -O $exp -h $hwc1 -h $hwc2 $exe -m $m -n $n -t 2
@end smallexample
@end cartouche

As before, we get a table with the event counts. Due to the very
long name for the second counter, we have somewhat modified the
output.

@cartouche
@smallexample
$ gprofng display text -limit 10 -functions mxv.hwc.sel.2.thr.er
@end smallexample
@end cartouche

@smallexample
@verbatim
Functions sorted by metric: Exclusive Total CPU Time
Excl.     Incl.     Excl. Branch  Excl.                 Name
Total     Total     Instructions  mem_load_retired.l1_miss
CPU sec.  CPU sec.                Events
2.597     2.597     1305305319    4021340               <Total>
2.481     2.481     1233233242    3982327               mxv_core
0.040     0.107       19019012       9003               init_data
0.028     0.052       23023048      15006               erand48_r
0.024     0.024       19019008       9004               __drand48_iterate
0.015     0.067       11011009       2998               drand48
0.008     0.010              0       3002               _int_malloc
0.001     0.001              0          0               brk
0.001     0.002              0          0               sysmalloc
0.        0.001              0          0               __default_morecore
@end verbatim
@end smallexample

@IndexSubentry{Commands, @code{compare ratio}}
When using event counters, the values could be very large and it is not easy
to compare the numbers. As we will show next, the @code{ratio} feature is
very useful when comparing such profiles.

To demonstrate this, we have set up another event counter experiment where
we would like to compare the number of last level cache miss and the number
of branch instructions executed when using a single thread, or two threads.

These are the commands used to generate the experiment directories:

@cartouche
@smallexample
$ exe=./mxv-pthreads.exe
$ m=3000
$ n=2000
$ exp1=mxv.hwc.comp.1.thr.er
$ exp2=mxv.hwc.comp.2.thr.er
$ gprofng collect app -O $exp1 -h llm -h br_ins $exe -m $m -n $n -t 1
$ gprofng collect app -O $exp2 -h llm -h br_ins $exe -m $m -n $n -t 2
@end smallexample
@end cartouche

The following script has been used to get the tables. Due to lay-out
restrictions, we have to create two tables, one for each counter.

@cartouche
@smallexample
# Limit the output to 5 lines
limit 5
# Define the metrics
metrics name:e.llm
# Set the comparison to ratio
compare ratio
functions
# Define the metrics
metrics name:e.br_ins
# Set the comparison to ratio
compare ratio
functions
@end smallexample
@end cartouche

Note that we print the name of the function first, followed by the counter 
data.
The new element is that we set the comparison mode to @code{ratio}. This
divides the data in a column by its counterpart in the reference experiment.

This is the command using this script and the two experiment directories as 
input:

@cartouche
@smallexample
$ gprofng display text -script my-script-comp-counters \
  mxv.hwc.comp.1.thr.er \
  mxv.hwc.comp.2.thr.er
@end smallexample
@end cartouche

By design, we get two tables, one for each counter:

@smallexample
@verbatim
Functions sorted by metric: Exclusive Last-Level Cache Misses

                              mxv.hwc.comp.1.thr.er  mxv.hwc.comp.2.thr.er
Name                          Excl. Last-Level       Excl. Last-Level
                              Cache Misses           Cache Misses
                                                         ratio
 <Total>                      122709276              x   0.788
 mxv_core                     121796001              x   0.787
 init_data                       723064              x   1.055
 erand48_r                       100111              x   0.500
 drand48                          60065              x   1.167

Functions sorted by metric: Exclusive Branch Instructions

                              mxv.hwc.comp.1.thr.er  mxv.hwc.comp.2.thr.er
Name                          Excl. Branch           Excl. Branch
                              Instructions           Instructions
                                                       ratio
 <Total>                      1307307316             x 0.997
 mxv_core                     1235235239             x 0.997
 erand48_r                      23023033             x 0.957
 drand48                        20020009             x 0.600
 __drand48_iterate              17017028             x 0.882
@end verbatim
@end smallexample

A ratio less than one in the second column, means that this counter
value was smaller than the value from the reference experiment shown
in the first column.

This kind of presentation of the results makes it much easier to 
quickly interpret the data.

We conclude this section with thread-level event counter overviews,
but before we go into this, there is an important metric we need to
mention.

@IndexSubentry{Hardware event counters, IPC}
In case it is known how many instructions and CPU cycles have been executed,
the value for the IPC (``Instructions Per Clockycle'') can be computed. 
@xref{Hardware Event Counters Explained}.
This is a derived metric that gives an indication how well the processor
is utilized. The inverse of the IPC is called CPI.

The @DisplayText{} command automatically computes the IPC and CPI values
if an experiment contains the event counter values for the instructions
and CPU cycles executed. These are part of the metric list and can be
displayed, just like any other metric.

@IndexSubentry{Commands, @code{metric_list}}
This can be verified through the @code{metric_list} command. If we go
back to our earlier experiment with the default event counters, we get
the following result.

@cartouche
@smallexample
$ gprofng display text -metric_list mxv.hwc.def.2.thr.er
@end smallexample
@end cartouche

@smallexample
@verbatim
Current metrics: e.totalcpu:i.totalcpu:e.cycles:e+insts:e+llm:name
Current Sort Metric: Exclusive Total CPU Time ( e.totalcpu )
Available metrics:
         Exclusive Total CPU Time: e.%totalcpu
         Inclusive Total CPU Time: i.%totalcpu
             Exclusive CPU Cycles: e.+%cycles
             Inclusive CPU Cycles: i.+%cycles
  Exclusive Instructions Executed: e+%insts
  Inclusive Instructions Executed: i+%insts
Exclusive Last-Level Cache Misses: e+%llm
Inclusive Last-Level Cache Misses: i+%llm
 Exclusive Instructions Per Cycle: e+IPC
 Inclusive Instructions Per Cycle: i+IPC
 Exclusive Cycles Per Instruction: e+CPI
 Inclusive Cycles Per Instruction: i+CPI
                             Size: size
                       PC Address: address
                             Name: name
@end verbatim
@end smallexample

Among the other metrics, we see the new metrics for the IPC and CPI 
listed.

In the script below, we use this information and add the IPC and CPI 
to the metrics to be displayed. We also use a the thread filter to 
display these values for the individual threads.

This is the complete script we have used. Other than a different selection
of the metrics, there are no new features.

@cartouche
@smallexample
# Define the metrics
metrics e.insts:e.%cycles:e.IPC:e.CPI
# Sort with respect to cycles
sort e.cycles
# Limit the output to 5 lines
limit 5
# Get the function overview for all threads
functions
# Get the function overview for thread 1
thread_select 1
functions
# Get the function overview for thread 2
thread_select 2
functions
# Get the function overview for thread 3
thread_select 3
functions
@end smallexample
@end cartouche

In the metrics definition on the second line, we explicitly request the 
counter values for the instructions (@code{e.insts}) and CPU cycles 
(@code{e.cycles}) executed. These names can be found in output from the
@code{metric_list} commad above.
In addition to these metrics, we also request the IPC and CPI to be shown.

As before, we used the @code{limit} command to control the number of 
functions displayed. We then request an overview for all the threads,
followed by three sets of two commands to select a thread and display the 
function overview.

The script above is used as follows:

@cartouche
@smallexample
$ gprofng display text -script my-script-ipc mxv.hwc.def.2.thr.er
@end smallexample
@end cartouche

This script produces four tables. We list them separately below,
and have left out the additional output.

The first table shows the accumulated values across the three
threads that have been active.

@smallexample
@verbatim
Functions sorted by metric: Exclusive CPU Cycles

Excl.         Excl. CPU     Excl.  Excl.   Name
Instructions  Cycles        IPC    CPI
Executed       sec.      %
7906475309    2.691 100.00  1.473  0.679   <Total>
7432724378    2.598  96.54  1.434  0.697   mxv_core
 188860269    0.035   1.31  2.682  0.373   erand48_r
  73623396    0.026   0.95  1.438  0.696   init_data
  76824434    0.018   0.66  2.182  0.458   drand48
@end verbatim
@end smallexample

This shows that IPC of this program is completely dominated
by function @code{mxv_core}. It has a fairly low IPC value
of 1.43.

The next table is for thread 1 and shows the values for the 
main thread.

@smallexample
@verbatim
Exp Sel Total
=== === =====
  1 1       3
Functions sorted by metric: Exclusive CPU Cycles

Excl.         Excl. CPU     Excl.  Excl.   Name
Instructions  Cycles        IPC    CPI
Executed       sec.      %
473750931     0.093 100.00  2.552  0.392   <Total>
188860269     0.035  37.93  2.682  0.373   erand48_r
 73623396     0.026  27.59  1.438  0.696   init_data
 76824434     0.018  18.97  2.182  0.458   drand48
134442832     0.013  13.79  5.250  0.190   __drand48_iterate
@end verbatim
@end smallexample

Although this thread hardly uses any CPU cycles, the overall IPC 
of 2.55 is not all that bad.

Last, we show the tables for threads 2 and 3:

@smallexample
@verbatim
Exp Sel Total
=== === =====
  1 2       3
Functions sorted by metric: Exclusive CPU Cycles

Excl.         Excl. CPU     Excl.  Excl.   Name
Instructions  Cycles        IPC    CPI
Executed       sec.      %
3716362189    1.298 100.00  1.435  0.697   <Total>
3716362189    1.298 100.00  1.435  0.697   mxv_core
         0    0.      0.    0.     0.      collector_root
         0    0.      0.    0.     0.      driver_mxv

Exp Sel Total
=== === =====
  1 3       3
Functions sorted by metric: Exclusive CPU Cycles

Excl.         Excl. CPU     Excl.  Excl.   Name
Instructions  Cycles        IPC    CPI
Executed       sec.      %
3716362189    1.300 100.00  1.433  0.698   <Total>
3716362189    1.300 100.00  1.433  0.698   mxv_core
         0    0.      0.    0.     0.      collector_root
         0    0.      0.    0.     0.      driver_mxv
@end verbatim
@end smallexample

It is seen that both execute the same number of instructions and
take about the same number of CPU cycles. As a result, the IPC is
the same for both threads.

@c -- A new node --------------------------------------------------------------
@c TBD @node    Additional Features
@c TBD @section Additional Features
@c ----------------------------------------------------------------------------

@c -- A new node --------------------------------------------------------------
@c TBD @node    More Filtering Capabilities
@c TBD @subsection More Filtering Capabilities
@c ----------------------------------------------------------------------------

@c TBD Cover @code{samples} and @code{seconds}

@c -- A new node --------------------------------------------------------------
@node    Java Profiling 
@section Java Profiling
@c ----------------------------------------------------------------------------

@IndexSubentry{Java profiling, @code{-j on/off}}
The @CollectApp{} command supports Java profiling. The @code{-j on} option
can be used for this, but since this feature is enabled by default, there is 
no need to set this explicitly. Java profiling may be disabled through the 
@code{-j off} option.

The program is compiled as usual and the experiment directory is created 
similar to what we have seen before. The only difference with a C/C++
application is that the program has to be explicitly executed by java.

For example, this is how to generate the experiment data for a Java
program that has the source code stored in file @code{Pi.java}:

@cartouche
@smallexample
$ javac Pi.java
$ gprofng collect app -j on -O pi.demo.er java Pi < pi.in
@end smallexample
@end cartouche

Regarding which java is selected to generate the data, @ToolName{} 
first looks for the JDK in the path set in either the 
@IndexSubentry{Java profiling, @code{JDK_HOME}}
@code{JDK_HOME} environment variable, or in the
@IndexSubentry{Java profiling, @code{JAVA_PATH}}
@code{JAVA_PATH} environment variable. If neither of these variables is 
set, it checks for a JDK in the search path (set in the PATH
environment variable). If there is no JDK in this path, it checks for 
the java executable in @code{/usr/java/bin/java}.

In case additional options need to be passed on to the JVM, the 
@IndexSubentry{Java profiling, @code{-J <string>}}
@code{-J <string>} option can be used. The string with the
option(s) has to be delimited by quotation marks in case
there is more than one argument.

The @DisplayText{} command may be used to view the performance data. There is
no need for any special options and the same commands as previously discussed
are supported.

@IndexSubentry{Commands, @code{viewmode}}
@IndexSubentry{Java profiling, different view modes}
The @code{viewmode} command 
@xref{The Viewmode}
is very useful to examine the call stacks. 

For example, this is how one can see the native call stacks. For
lay-out purposes we have restricted the list to the first five entries:

@cartouche
@smallexample
$ gprofng display text -limit 5 -viewmode machine -calltree pi.demo.er 
@end smallexample
@end cartouche

@smallexample
@verbatim
Print limit set to 5
Viewmode set to machine
Functions Call Tree. Metric: Attributed Total CPU Time

Attr.      Name
Total
CPU sec.
1.381      +-<Total>
1.171        +-Pi.calculatePi(double)
0.110        +-collector_root
0.110        |  +-JavaMain
0.070        |    +-jni_CallStaticVoidMethod
@end verbatim
@end smallexample

@noindent
Note that the selection of the viewmode is echoed in the output.

@c -- A new node --------------------------------------------------------------
@c TBD @node Summary of Options and Commands
@c TBD @chapter Summary of Options and Commands
@c ----------------------------------------------------------------------------

@c -- A new node --------------------------------------------------------------
@node    Terminology
@chapter Terminology

Throughout this manual, certain terminology specific to profiling tools, 
or @ToolName{}, or even to this document only, is used. In this chapter we 
explain this terminology in detail.

@menu
* The Program Counter::                    What is a Program Counter?
* Inclusive and Exclusive Metrics::        An explanation of inclusive and exclusive metrics.
* Metric Definitions::                     Definitions associated with metrics.
* The Viewmode::                           Select the way call stacks are presented.
* The Selection List::                     How to define a selection.
* Load Objects and Functions::             The components in an application.
* The Concept of a CPU in @ProductName{}:: The definition of a CPU.
* Hardware Event Counters Explained::      What are event counters?
* apath::                                  Our generic definition of a path.
@end menu

@c ----------------------------------------------------------------------------
@node    The Program Counter
@section The Program Counter
@c ----------------------------------------------------------------------------

@cindex PC
@cindex Program Counter
The @emph{Program Counter}, or PC for short, keeps track where program execution is.
The address of the next instruction to be executed is stored in a special
purpose register in the processor, or core.

@cindex Instruction pointer
The PC is sometimes also referred to as the @emph{instruction pointer}, but
we will use Program Counter or PC throughout this document.

@c ----------------------------------------------------------------------------
@node    Inclusive and Exclusive Metrics
@section Inclusive and Exclusive Metrics
@c ----------------------------------------------------------------------------

In the remainder, these two concepts occur quite often and for lack of a better
place, they are explained here.

@cindex Inclusive metric
The @emph{inclusive} value for a metric includes all values that are part of
the dynamic extent of the target function. For example if function @code{A}
calls functions @code{B} and @code{C}, the inclusive CPU time for @code{A} 
includes the CPU time spent in @code{B} and @code{C}.

@cindex Exclusive metric
In contrast with this, the @emph{exclusive} value for a metric is computed
by excluding the metric values used by other functions called. In our imaginary
example, the exclusive CPU time for function @code{A} is the time spent outside
calling functions @code{B} and @code{C}.

@cindex Leaf function
In case of a @emph{leaf function}, the inclusive and exclusive values for the 
metric are the same since by definition, it is not calling any other 
function(s).

Why do we use these two different values? The inclusive metric shows the most
expensive path, in terms of this metric, in the application. For example, if
the metric is cache misses, the function with the highest inclusive metric
tells you where most of the cache misses come from.

Within this branch of the application, the exclusive metric points to the
functions that contribute and help to identify which part(s) to consider
for further analysis.

@c ----------------------------------------------------------------------------
@node    Metric Definitions
@section Metric Definitions
@c ----------------------------------------------------------------------------
The metrics to be shown are highly customizable. In this section we explain 
the definitions associated with metrics.

@IndexSubentry{Commands, @code{metrics}}
The @code{metrics} command takes a colon (:) separated list with special
keywords. This keyword consists of the following three fields: 
@code{<flavor>}@code{<visibility>}@code{<metric_name>}.

@cindex Flavor field
@cindex Visibility field
@cindex Metric name field
The @emph{<flavor>} field is either an @code{e} for ``exclusive'', or @code{i}
for ``inclusive''. The @code{<metric_name>} field is the name of the metric
request. The @emph{<visibility>} field consists of one ore more characters
from the following table:

@table @code

@item .
Show the metric as time. This applies to timing metrics and hardware event counters
that measure cycles. Interpret as @code{+} for other metrics.

@item %
Show the metric as a percentage of the total value for this metric.

@item +
Show the metric as an absolute value. For hardware event counters this is
the event count. Interpret as @code{.} for timing metrics.

@item |
Do not show any metric value. Cannot be used with other visibility characters.

@end table 

@c ----------------------------------------------------------------------------
@node    The Viewmode
@section The Viewmode

@cindex Viewmode
@IndexSubentry{Commands, @code{viewmode}}

There are different ways to view a call stack in Java. In @ToolName{}, this
is called the @emph{viewmode} and the setting is controlled through a command
with the same name.

The @code{viewmode} command takes one of the following keywords:

@table @code

@item user
This is the default and shows the Java call stacks for Java threads.
No call stacks for any housekeeping threads are shown. The function 
list contains a function 
@IndexSubentry{Java profiling, @code{<JVM-System>}}
@code{<JVM-System>} that represents the aggregated time from non-Java
threads.
When the JVM software does not report a Java call stack, time is reported
against the function 
@IndexSubentry{Java profiling, @code{<no Java callstack recorded>}}
@code{<no Java callstack recorded>}.


@item expert
Show the Java call stacks for Java threads when the Java code from the
user is executed and machine call stacks when JVM code is executed, or 
when the JVM software does not report a Java call stack. 
Show the machine call stacks for housekeeping threads.

@item machine
Show the actual native call stacks for all threads.

@end table

@c ----------------------------------------------------------------------------
@c ----------------------------------------------------------------------------
@node    The Selection List
@section The Selection List
@c ----------------------------------------------------------------------------

@cindex Selection list
@cindex List specification
Several commands allow the user to specify a subset of a list. For example,
to select specific threads from all the threads that have been used when 
conducting the experiment(s). 

Such a selection list (or ``list'' in the remainder of this section) can be a 
single number, a contiguous range of numbers with the start and end numbers 
separated by a hyphen (@code{-}), a comma-separated list of numbers and 
ranges, or the @code{all} keyword. Lists must not contain spaces. 

Each list can optionally be preceded by an experiment list with a similar 
format, separated from the list by a colon (:). 
If no experiment list is included, the list applies to all experiments.

Multiple lists can be concatenated by separating the individual lists 
by a plus sign.

These are some examples of various filters using a list:

@table @code

@item thread_select 1
Select thread 1 from all experiments.

@item thread_select all:1
Select thread 1 from all experiments.

@item thread_select 1:1+2:2
Select thread 1 from experiment 1 and thread 2 from experiment 2.

@item cpu_select all:1,3,5
Selects cores 1, 3, and 5 from all experiments.

@item cpu_select 1,2:all
Select all cores from experiments 1 and 2, as listed by the @code{by exp_list} command.

@end table

@c ----------------------------------------------------------------------------
@node    Load Objects and Functions
@section Load Objects and Functions
@c ----------------------------------------------------------------------------

An application consists of various components. The source code files are 
compiled into object files. These are then glued together at link time to form
the executable. 
During execution, the program may also dynamically load objects.

@cindex Load object 
A @emph{load object} is defined to be an executable, or shared object. A shared
library is an example of a load object in @ToolName{}.

Each load object, contains a text section with the instructions generated by the 
compiler, a data section for data, and various symbol tables.
All load objects must contain an 
@cindex ELF
ELF 
symbol table, which gives the names and addresses of all the globally known 
functions in that object. 

Load objects compiled with the -g option contain additional symbolic information 
that can augment the ELF symbol table and provide information about functions that 
are not global, additional information about object modules from which the functions 
came, and line number information relating addresses to source lines.

The term
@cindex Function
@emph{function}
is used to describe a set of instructions that represent a high-level operation 
described in the source code. The term also covers methods as used in C++ and in
the Java programming language. 

In the @ToolName{} context, functions are provided in source code format. 
Normally their names appear in the symbol table representing a set of addresses. 
@cindex Program Counter
@cindex PC
If the Program Counter (PC) is within that set, the program is executing within that function.

In principle, any address within the text segment of a load object can be mapped to a 
function. Exactly the same mapping is used for the leaf PC and all the other PCs on the 
call stack. 

Most of the functions correspond directly to the source model of the program, but 
there are exceptions. This topic is however outside of the scope of this guide.

@c ----------------------------------------------------------------------------
@node    The Concept of a CPU in @ProductName{}
@section The Concept of a CPU in @ProductName{}
@c ----------------------------------------------------------------------------

@cindex CPU
In @ProductName{}, there is the concept of a CPU. Admittedly, this is not the
best word to describe what is meant here and may be replaced in the future.

The word CPU is used in many of the displays.
In the context of @ProductName{}, it is meant to denote a part of the 
processor that is capable of executing instructions and with its own state, 
like the program counter.

For example, on a contemporary processor, a CPU could be a core. In case
hardware threads are supported within a core, it could be one of those
hardware threads.

@c ----------------------------------------------------------------------------
@node    Hardware Event Counters Explained
@section Hardware Event Counters Explained
@c ----------------------------------------------------------------------------

@IndexSubentry{Hardware event counters, description}
For quite a number of years now, many microprocessors have supported hardware 
event counters. 

On the hardware side, this means that in the processor there are one or more 
registers dedicated to count certain activities, or ``events''.
Examples of such events are the number of instructions executed, or the number 
of cache misses at level 2 in the memory hierarchy.

While there is a limited set of such registers, the user can map events onto
them. In case more than one register is available, this allows for the 
simultaenous measurement of various events.

A simple, yet powerful, example is to simultaneously count the number of CPU 
cycles and the number of instructions excuted. These two numbers can then be
used to compute the 
@cindex IPC
@emph{IPC} value. IPC stands for ``Instructions Per Clockcycle'' and each processor 
has a maximum. For example, if this maximum number is 2, it means the 
processor is capable of executing two instructions every clock cycle.

Whether this is actually achieved, depends on several factors, including the
instruction characteristics.
However, in case the IPC value is well below this maximum in a time critical 
part of the application and this cannot be easily explained, further 
investigation is probably warranted.

@cindex CPI
A related metric is called @emph{CPI}, or ``Clockcycles Per Instruction''.
It is the inverse of the CPI and can be compared against the theoretical
value(s) of the target instruction(s). A significant difference may point
at a bottleneck.

One thing to keep in mind is that the value returned by a counter can either
be the number of times the event occured, or a CPU cycle count. In case of 
the latter it is possible to convert this number to time.

@IndexSubentry{Hardware event counters, variable CPU frequency}
This is often easier to interpret than a simple count, but there is one
caveat to keep in mind. The CPU frequency may not have been constant while
the experimen was recorded and this impacts the time reported.

These event counters, or ``counters'' for short, provide great insight into
what happens deep inside the processor. In case higher level information does
not provide the insight needed, the counters provide the information to get 
to the bottom of a performance problem.

There are some things to consider though. 

@itemize @bullet

@item
The event definitions and names vary across processors and it may even happen 
that some events change with an update.
Unfortunately and this is luckily rare, there are sometimes bugs causing the 
wrong count to be returned.

@IndexSubentry{Hardware event counters, alias name}
In @ToolName{}, some of the processor specific event names have an alias 
name. For example @code{insts} measures the instructions executed. 
These aliases not only makes it easier to identify the functionality, but also 
provide portability of certain events across processors.

@item
Another complexity is that there are typically many events one can monitor.
There may up to hundreds of events available and it could require several
experiments to zoom in on the root cause of a performance problem.

@item
There may be restrictions regarding the mapping of event(s) onto the 
counters. For example, certain events may be restricted to specific 
counters only. As a result, one may have to conduct additional experiments
to cover all the events of interest.

@item
The names of the events may also not be easy to interpret. In such cases,
the description can be found in the architecture manual for the processor.

@end itemize

Despite these drawbacks, hardware event counters are extremely useful and
may even turn out to be indispensable.

@c ----------------------------------------------------------------------------
@node    apath
@section What is <apath>?
@c ----------------------------------------------------------------------------

In most cases, @ToolName{} shows the absolute pathnames of directories. These
tend to be rather long, causing display issues in this document. 

Instead of wrapping these long pathnames over multiple lines, we decided to 
represent them by the @code{<apath>} symbol, which stands for ``an absolute 
pathname''.

Note that different occurrences of @code{<apath>} may represent different
absolute pathnames.

@c -- A new node --------------------------------------------------------------
@node    Other Document Formats
@chapter Other Document Formats
@c ----------------------------------------------------------------------------

This document is written in Texinfo and the source text is made available as
part of the binutils distribution. The file name is @code{gprofng.texi} and
can be found in subdirectory @code{doc} under directory @code{gprofng} in the 
top level directory.

This file can be used to generate the document in the @code{info}, @code{html}, 
and @code{pdf} formats.
The default installation procedure creates a file in the @code{info} format and 
stores it in the documentation section of binutils.

The probably easiest way to generate a different format from this Texinfo 
document is to go to the distribution directory that was created when the 
tools were built.
This is either the default distribution directory, or the one that has been set
with the @code{--prefix} option as part of the @code{configure} command.
In this example we symbolize this location with @code{<dist>}.

The make file called @code{Makefile} in directory @code{<dist>/gprofng/doc}
supports several commands to generate this document in different formats. 
We recommend to use these commands.

They create the file(s) and install it in the documentation directory of binutils,
which is @code{<dist>/share/doc} in case @code{html} or @code{pdf} is selected and
@code{<dist>/share/info} for the file in the @code{info} format.

To generate this document in the requested format and install it in the documentation 
directory, the commands below should be executed. In this notation, @code{<format>} 
is one of @code{info}, @code{html}, or @code{pdf}:

@smallexample
@verbatim
$ cd <dist>/gprofng/doc
$ make install-<format>
@end verbatim
@end smallexample

@noindent
Some things to note:

@itemize

@item
For the @code{pdf} file to be generated, the 
@cindex TeX
TeX document formatting software is required and the relevant commmands need
to be included in the search path. An example of a popular TeX implementation 
is @emph{TexLive}. It is beyond the scope of this document to go into the
details of installing and using TeX, but it is well documented elsewhere.

@item
Instead of generating a single file in the @code{html} format, it is also 
possible to create a directory with individual files for the various chapters. 
To do so, remove the use of @code{--no-split} in variable @code{MAKEINFOHTML}
in the make file in the @code{doc} directory.

@item
The make file also supports commands to only generate the file in the desired
format and not move them to the documentation directory. This is
accomplished through the @code{make <format>} command.

@end itemize

@ifnothtml
@node       Index
@unnumbered Index
@printindex cp
@end ifnothtml

@bye
